packer-cn/hcl2template/types.packer_config.go

629 lines
17 KiB
Go

package hcl2template
import (
"fmt"
"sort"
"strings"
"github.com/gobwas/glob"
"github.com/hashicorp/hcl/v2"
"github.com/hashicorp/hcl/v2/hcldec"
"github.com/hashicorp/hcl/v2/hclsyntax"
packersdk "github.com/hashicorp/packer-plugin-sdk/packer"
pkrfunction "github.com/hashicorp/packer/hcl2template/function"
"github.com/hashicorp/packer/packer"
"github.com/zclconf/go-cty/cty"
"github.com/zclconf/go-cty/cty/function"
)
// PackerConfig represents a loaded Packer HCL config. It will contain
// references to all possible blocks of the allowed configuration.
type PackerConfig struct {
Packer struct {
VersionConstraints []VersionConstraint
}
// Directory where the config files are defined
Basedir string
// Core Packer version, for reference by plugins and template functions.
CorePackerVersionString string
// directory Packer was called from
Cwd string
// Available Source blocks
Sources map[SourceRef]SourceBlock
// InputVariables and LocalVariables are the list of defined input and
// local variables. They are of the same type but are not used in the same
// way. Local variables will not be decoded from any config file, env var,
// or ect. Like the Input variables will.
InputVariables Variables
LocalVariables Variables
Datasources Datasources
LocalBlocks []*LocalBlock
ValidationOptions
// Builds is the list of Build blocks defined in the config files.
Builds Builds
builderSchemas packer.BuilderStore
provisionersSchemas packer.ProvisionerStore
postProcessorsSchemas packer.PostProcessorStore
datasourceSchemas packer.DatasourceStore
except []glob.Glob
only []glob.Glob
parser *Parser
files []*hcl.File
}
type ValidationOptions struct {
Strict bool
}
const (
inputVariablesAccessor = "var"
localsAccessor = "local"
pathVariablesAccessor = "path"
sourcesAccessor = "source"
buildAccessor = "build"
packerAccessor = "packer"
dataAccessor = "data"
)
// EvalContext returns the *hcl.EvalContext that will be passed to an hcl
// decoder in order to tell what is the actual value of a var or a local and
// the list of defined functions.
func (cfg *PackerConfig) EvalContext(variables map[string]cty.Value) *hcl.EvalContext {
inputVariables, _ := cfg.InputVariables.Values()
localVariables, _ := cfg.LocalVariables.Values()
datasourceVariables, _ := cfg.Datasources.Values()
ectx := &hcl.EvalContext{
Functions: Functions(cfg.Basedir),
Variables: map[string]cty.Value{
inputVariablesAccessor: cty.ObjectVal(inputVariables),
localsAccessor: cty.ObjectVal(localVariables),
sourcesAccessor: cty.ObjectVal(map[string]cty.Value{
"type": cty.UnknownVal(cty.String),
"name": cty.UnknownVal(cty.String),
}),
buildAccessor: cty.UnknownVal(cty.EmptyObject),
packerAccessor: cty.ObjectVal(map[string]cty.Value{
"version": cty.StringVal(cfg.CorePackerVersionString),
}),
pathVariablesAccessor: cty.ObjectVal(map[string]cty.Value{
"cwd": cty.StringVal(strings.ReplaceAll(cfg.Cwd, `\`, `/`)),
"root": cty.StringVal(strings.ReplaceAll(cfg.Basedir, `\`, `/`)),
}),
dataAccessor: cty.ObjectVal(datasourceVariables),
},
}
for k, v := range variables {
ectx.Variables[k] = v
}
return ectx
}
// decodeInputVariables looks in the found blocks for 'variables' and
// 'variable' blocks. It should be called firsthand so that other blocks can
// use the variables.
func (c *PackerConfig) decodeInputVariables(f *hcl.File) hcl.Diagnostics {
var diags hcl.Diagnostics
content, moreDiags := f.Body.Content(configSchema)
diags = append(diags, moreDiags...)
// for input variables we allow to use env in the default value section.
ectx := &hcl.EvalContext{
Functions: map[string]function.Function{
"env": pkrfunction.EnvFunc,
},
}
for _, block := range content.Blocks {
switch block.Type {
case variableLabel:
moreDiags := c.InputVariables.decodeVariableBlock(block, ectx)
diags = append(diags, moreDiags...)
case variablesLabel:
attrs, moreDiags := block.Body.JustAttributes()
diags = append(diags, moreDiags...)
for key, attr := range attrs {
moreDiags = c.InputVariables.decodeVariable(key, attr, ectx)
diags = append(diags, moreDiags...)
}
}
}
return diags
}
// parseLocalVariables looks in the found blocks for 'locals' blocks. It
// should be called after parsing input variables so that they can be
// referenced.
func (c *PackerConfig) parseLocalVariables(f *hcl.File) ([]*LocalBlock, hcl.Diagnostics) {
var diags hcl.Diagnostics
content, moreDiags := f.Body.Content(configSchema)
diags = append(diags, moreDiags...)
var locals []*LocalBlock
for _, block := range content.Blocks {
switch block.Type {
case localsLabel:
attrs, moreDiags := block.Body.JustAttributes()
diags = append(diags, moreDiags...)
for name, attr := range attrs {
if _, found := c.LocalVariables[name]; found {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: "Duplicate value in " + localsLabel,
Detail: "Duplicate " + name + " definition found.",
Subject: attr.NameRange.Ptr(),
Context: block.DefRange.Ptr(),
})
return nil, diags
}
locals = append(locals, &LocalBlock{
Name: name,
Expr: attr.Expr,
})
}
}
}
return locals, diags
}
func (c *PackerConfig) evaluateLocalVariables(locals []*LocalBlock) hcl.Diagnostics {
var diags hcl.Diagnostics
if len(locals) > 0 && c.LocalVariables == nil {
c.LocalVariables = Variables{}
}
var retry, previousL int
for len(locals) > 0 {
local := locals[0]
moreDiags := c.evaluateLocalVariable(local)
if moreDiags.HasErrors() {
if len(locals) == 1 {
// If this is the only local left there's no need
// to try evaluating again
return append(diags, moreDiags...)
}
if previousL == len(locals) {
if retry == 100 {
// To get to this point, locals must have a circle dependency
return append(diags, moreDiags...)
}
retry++
}
previousL = len(locals)
// If local uses another local that has not been evaluated yet this could be the reason of errors
// Push local to the end of slice to be evaluated later
locals = append(locals, local)
} else {
retry = 0
diags = append(diags, moreDiags...)
}
// Remove local from slice
locals = append(locals[:0], locals[1:]...)
}
return diags
}
func (c *PackerConfig) evaluateLocalVariable(local *LocalBlock) hcl.Diagnostics {
var diags hcl.Diagnostics
value, moreDiags := local.Expr.Value(c.EvalContext(nil))
diags = append(diags, moreDiags...)
if moreDiags.HasErrors() {
return diags
}
c.LocalVariables[local.Name] = &Variable{
Name: local.Name,
Values: []VariableAssignment{{
Value: value,
Expr: local.Expr,
From: "default",
}},
Type: value.Type(),
}
return diags
}
func (cfg *PackerConfig) evaluateDatasources(skipExecution bool) hcl.Diagnostics {
var diags hcl.Diagnostics
for ref, ds := range cfg.Datasources {
if ds.value != (cty.Value{}) {
continue
}
datasource, startDiags := cfg.startDatasource(cfg.datasourceSchemas, ref)
diags = append(diags, startDiags...)
if diags.HasErrors() {
continue
}
if skipExecution {
placeholderValue := cty.UnknownVal(hcldec.ImpliedType(datasource.OutputSpec()))
ds.value = placeholderValue
cfg.Datasources[ref] = ds
continue
}
realValue, err := datasource.Execute()
if err != nil {
diags = append(diags, &hcl.Diagnostic{
Summary: err.Error(),
Subject: &cfg.Datasources[ref].block.DefRange,
Severity: hcl.DiagError,
})
continue
}
ds.value = realValue
cfg.Datasources[ref] = ds
}
return diags
}
// getCoreBuildProvisioners takes a list of provisioner block, starts according
// provisioners and sends parsed HCL2 over to it.
func (cfg *PackerConfig) getCoreBuildProvisioners(source SourceBlock, blocks []*ProvisionerBlock, ectx *hcl.EvalContext) ([]packer.CoreBuildProvisioner, hcl.Diagnostics) {
var diags hcl.Diagnostics
res := []packer.CoreBuildProvisioner{}
for _, pb := range blocks {
if pb.OnlyExcept.Skip(source.String()) {
continue
}
provisioner, moreDiags := cfg.startProvisioner(source, pb, ectx)
diags = append(diags, moreDiags...)
if moreDiags.HasErrors() {
continue
}
// If we're pausing, we wrap the provisioner in a special pauser.
if pb.PauseBefore != 0 {
provisioner = &packer.PausedProvisioner{
PauseBefore: pb.PauseBefore,
Provisioner: provisioner,
}
} else if pb.Timeout != 0 {
provisioner = &packer.TimeoutProvisioner{
Timeout: pb.Timeout,
Provisioner: provisioner,
}
}
if pb.MaxRetries != 0 {
provisioner = &packer.RetriedProvisioner{
MaxRetries: pb.MaxRetries,
Provisioner: provisioner,
}
}
res = append(res, packer.CoreBuildProvisioner{
PType: pb.PType,
PName: pb.PName,
Provisioner: provisioner,
})
}
return res, diags
}
// getCoreBuildProvisioners takes a list of post processor block, starts
// according provisioners and sends parsed HCL2 over to it.
func (cfg *PackerConfig) getCoreBuildPostProcessors(source SourceBlock, blocksList [][]*PostProcessorBlock, ectx *hcl.EvalContext) ([][]packer.CoreBuildPostProcessor, hcl.Diagnostics) {
var diags hcl.Diagnostics
res := [][]packer.CoreBuildPostProcessor{}
for _, blocks := range blocksList {
pps := []packer.CoreBuildPostProcessor{}
for _, ppb := range blocks {
if ppb.OnlyExcept.Skip(source.String()) {
continue
}
name := ppb.PName
if name == "" {
name = ppb.PType
}
// -except
exclude := false
for _, exceptGlob := range cfg.except {
if exceptGlob.Match(name) {
exclude = true
break
}
}
if exclude {
break
}
postProcessor, moreDiags := cfg.startPostProcessor(source, ppb, ectx)
diags = append(diags, moreDiags...)
if moreDiags.HasErrors() {
continue
}
pps = append(pps, packer.CoreBuildPostProcessor{
PostProcessor: postProcessor,
PName: ppb.PName,
PType: ppb.PType,
KeepInputArtifact: ppb.KeepInputArtifact,
})
}
if len(pps) > 0 {
res = append(res, pps)
}
}
return res, diags
}
// GetBuilds returns a list of packer Build based on the HCL2 parsed build
// blocks. All Builders, Provisioners and Post Processors will be started and
// configured.
func (cfg *PackerConfig) GetBuilds(opts packer.GetBuildsOptions) ([]packersdk.Build, hcl.Diagnostics) {
res := []packersdk.Build{}
var diags hcl.Diagnostics
for _, build := range cfg.Builds {
for _, from := range build.Sources {
src, found := cfg.Sources[from.Ref()]
if !found {
diags = append(diags, &hcl.Diagnostic{
Summary: "Unknown " + sourceLabel + " " + from.String(),
Subject: build.HCL2Ref.DefRange.Ptr(),
Severity: hcl.DiagError,
Detail: fmt.Sprintf("Known: %v", cfg.Sources),
})
continue
}
src.addition = from.addition
src.LocalName = from.LocalName
pcb := &packer.CoreBuild{
BuildName: build.Name,
Type: src.String(),
}
// Apply the -only and -except command-line options to exclude matching builds.
buildName := pcb.Name()
// -only
if len(opts.Only) > 0 {
onlyGlobs, diags := convertFilterOption(opts.Only, "only")
if diags.HasErrors() {
return nil, diags
}
cfg.only = onlyGlobs
include := false
for _, onlyGlob := range onlyGlobs {
if onlyGlob.Match(buildName) {
include = true
break
}
}
if !include {
continue
}
}
// -except
if len(opts.Except) > 0 {
exceptGlobs, diags := convertFilterOption(opts.Except, "except")
if diags.HasErrors() {
return nil, diags
}
cfg.except = exceptGlobs
exclude := false
for _, exceptGlob := range exceptGlobs {
if exceptGlob.Match(buildName) {
exclude = true
break
}
}
if exclude {
continue
}
}
builder, moreDiags, generatedVars := cfg.startBuilder(src, cfg.EvalContext(nil), opts)
diags = append(diags, moreDiags...)
if moreDiags.HasErrors() {
continue
}
// If the builder has provided a list of to-be-generated variables that
// should be made accessible to provisioners, pass that list into
// the provisioner prepare() so that the provisioner can appropriately
// validate user input against what will become available. Otherwise,
// only pass the default variables, using the basic placeholder data.
unknownBuildValues := map[string]cty.Value{}
for _, k := range append(packer.BuilderDataCommonKeys, generatedVars...) {
unknownBuildValues[k] = cty.StringVal("<unknown>")
}
unknownBuildValues["name"] = cty.StringVal(build.Name)
variables := map[string]cty.Value{
sourcesAccessor: cty.ObjectVal(src.ctyValues()),
buildAccessor: cty.ObjectVal(unknownBuildValues),
}
provisioners, moreDiags := cfg.getCoreBuildProvisioners(src, build.ProvisionerBlocks, cfg.EvalContext(variables))
diags = append(diags, moreDiags...)
if moreDiags.HasErrors() {
continue
}
pps, moreDiags := cfg.getCoreBuildPostProcessors(src, build.PostProcessorsLists, cfg.EvalContext(variables))
diags = append(diags, moreDiags...)
if moreDiags.HasErrors() {
continue
}
pcb.Builder = builder
pcb.Provisioners = provisioners
pcb.PostProcessors = pps
pcb.Prepared = true
// Prepare just sets the "prepareCalled" flag on CoreBuild, since
// we did all the prep here.
_, err := pcb.Prepare()
if err != nil {
diags = append(diags, &hcl.Diagnostic{
Severity: hcl.DiagError,
Summary: fmt.Sprintf("Preparing packer core build %s failed", src.Ref().String()),
Detail: err.Error(),
Subject: build.HCL2Ref.DefRange.Ptr(),
})
continue
}
res = append(res, pcb)
}
}
return res, diags
}
var PackerConsoleHelp = strings.TrimSpace(`
Packer console HCL2 Mode.
The Packer console allows you to experiment with Packer interpolations.
You may access variables and functions in the Packer config you called the
console with.
Type in the interpolation to test and hit <enter> to see the result.
"upper(var.foo.id)" would evaluate to the ID of "foo" and uppercase is, if it
exists in your config file.
"variables" will dump all available variables and their values.
To exit the console, type "exit" and hit <enter>, or use Control-C.
/!\ It is not possible to use go templating interpolation like "{{timestamp}}"
with in HCL2 mode.
`)
func (p *PackerConfig) EvaluateExpression(line string) (out string, exit bool, diags hcl.Diagnostics) {
switch {
case line == "":
return "", false, nil
case line == "exit":
return "", true, nil
case line == "help":
return PackerConsoleHelp, false, nil
case line == "variables":
return p.printVariables(), false, nil
default:
return p.handleEval(line)
}
}
func (p *PackerConfig) printVariables() string {
out := &strings.Builder{}
out.WriteString("> input-variables:\n\n")
keys := p.InputVariables.Keys()
sort.Strings(keys)
for _, key := range keys {
v := p.InputVariables[key]
val, _ := v.Value()
fmt.Fprintf(out, "var.%s: %q\n", v.Name, PrintableCtyValue(val))
}
out.WriteString("\n> local-variables:\n\n")
keys = p.LocalVariables.Keys()
sort.Strings(keys)
for _, key := range keys {
v := p.LocalVariables[key]
val, _ := v.Value()
fmt.Fprintf(out, "local.%s: %q\n", v.Name, PrintableCtyValue(val))
}
return out.String()
}
func (p *PackerConfig) printBuilds() string {
out := &strings.Builder{}
out.WriteString("> builds:\n")
for i, build := range p.Builds {
name := build.Name
if name == "" {
name = fmt.Sprintf("<unnamed build %d>", i)
}
fmt.Fprintf(out, "\n > %s:\n", name)
if build.Description != "" {
fmt.Fprintf(out, "\n > Description: %s\n", build.Description)
}
fmt.Fprintf(out, "\n sources:\n")
if len(build.Sources) == 0 {
fmt.Fprintf(out, "\n <no source>\n")
}
for _, source := range build.Sources {
fmt.Fprintf(out, "\n %s\n", source)
}
fmt.Fprintf(out, "\n provisioners:\n\n")
if len(build.ProvisionerBlocks) == 0 {
fmt.Fprintf(out, " <no provisioner>\n")
}
for _, prov := range build.ProvisionerBlocks {
str := prov.PType
if prov.PName != "" {
str = strings.Join([]string{prov.PType, prov.PName}, ".")
}
fmt.Fprintf(out, " %s\n", str)
}
fmt.Fprintf(out, "\n post-processors:\n")
if len(build.PostProcessorsLists) == 0 {
fmt.Fprintf(out, "\n <no post-processor>\n")
}
for i, ppList := range build.PostProcessorsLists {
fmt.Fprintf(out, "\n %d:\n", i)
for _, pp := range ppList {
str := pp.PType
if pp.PName != "" {
str = strings.Join([]string{pp.PType, pp.PName}, ".")
}
fmt.Fprintf(out, " %s\n", str)
}
}
}
return out.String()
}
func (p *PackerConfig) handleEval(line string) (out string, exit bool, diags hcl.Diagnostics) {
// Parse the given line as an expression
expr, parseDiags := hclsyntax.ParseExpression([]byte(line), "<console-input>", hcl.Pos{Line: 1, Column: 1})
diags = append(diags, parseDiags...)
if parseDiags.HasErrors() {
return "", false, diags
}
val, valueDiags := expr.Value(p.EvalContext(nil))
diags = append(diags, valueDiags...)
if valueDiags.HasErrors() {
return "", false, diags
}
return PrintableCtyValue(val), false, diags
}
func (p *PackerConfig) FixConfig(_ packer.FixConfigOptions) (diags hcl.Diagnostics) {
// No Fixers exist for HCL2 configs so there is nothing to do here for now.
return
}
func (p *PackerConfig) InspectConfig(opts packer.InspectConfigOptions) int {
ui := opts.Ui
ui.Say("Packer Inspect: HCL2 mode\n")
ui.Say(p.printVariables())
ui.Say(p.printBuilds())
return 0
}