packer-cn/command/hcl2_upgrade.go

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package command
import (
"bytes"
"context"
"fmt"
"io"
"os"
"path/filepath"
"sort"
"strings"
texttemplate "text/template"
"github.com/hashicorp/hcl/v2/hclwrite"
hcl2shim "github.com/hashicorp/packer/hcl2template/shim"
"github.com/hashicorp/packer/template"
"github.com/posener/complete"
"github.com/zclconf/go-cty/cty"
)
type HCL2UpgradeCommand struct {
Meta
}
func (c *HCL2UpgradeCommand) Run(args []string) int {
ctx, cleanup := handleTermInterrupt(c.Ui)
defer cleanup()
cfg, ret := c.ParseArgs(args)
if ret != 0 {
return ret
}
return c.RunContext(ctx, cfg)
}
func (c *HCL2UpgradeCommand) ParseArgs(args []string) (*HCL2UpgradeArgs, int) {
var cfg HCL2UpgradeArgs
flags := c.Meta.FlagSet("hcl2_upgrade", FlagSetNone)
flags.Usage = func() { c.Ui.Say(c.Help()) }
cfg.AddFlagSets(flags)
if err := flags.Parse(args); err != nil {
return &cfg, 1
}
args = flags.Args()
if len(args) != 1 {
flags.Usage()
return &cfg, 1
}
cfg.Path = args[0]
if cfg.OutputFile == "" {
cfg.OutputFile = cfg.Path + ".pkr.hcl"
}
return &cfg, 0
}
const (
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hcl2UpgradeFileHeader = `# This file was autogenerated by the BETA 'packer hcl2_upgrade' command. We
# recommend double checking that everything is correct before going forward. We
# also recommend treating this file as disposable. The HCL2 blocks in this
# file can be moved to other files. For example, the variable blocks could be
# moved to their own 'variables.pkr.hcl' file, etc. Those files need to be
# suffixed with '.pkr.hcl' to be visible to Packer. To use multiple files at
# once they also need to be in the same folder. 'packer inspect folder/'
# will describe to you what is in that folder.
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# All generated input variables will be of 'string' type as this is how Packer JSON
# views them; you can change their type later on. Read the variables type
# constraints documentation
# https://www.packer.io/docs/from-1.5/variables#type-constraints for more info.
`
sourcesHeader = `
# source blocks are generated from your builders; a source can be referenced in
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# build blocks. A build block runs provisioner and post-processors on a
# source. Read the documentation for source blocks here:
# https://www.packer.io/docs/from-1.5/blocks/source`
buildHeader = `
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# a build block invokes sources and runs provisioning steps on them. The
# documentation for build blocks can be found here:
# https://www.packer.io/docs/from-1.5/blocks/build
build {
`
)
func (c *HCL2UpgradeCommand) RunContext(buildCtx context.Context, cla *HCL2UpgradeArgs) int {
out := &bytes.Buffer{}
var output io.Writer
if err := os.MkdirAll(filepath.Dir(cla.OutputFile), 0); err != nil {
c.Ui.Error(fmt.Sprintf("Failed to create output directory: %v", err))
return 1
}
if f, err := os.Create(cla.OutputFile); err == nil {
output = f
defer f.Close()
} else {
c.Ui.Error(fmt.Sprintf("Failed to create output file: %v", err))
return 1
}
if _, err := output.Write([]byte(hcl2UpgradeFileHeader)); err != nil {
c.Ui.Error(fmt.Sprintf("Failed to write to file: %v", err))
return 1
}
hdl, ret := c.GetConfigFromJSON(&cla.MetaArgs)
if ret != 0 {
return ret
}
core := hdl.(*CoreWrapper).Core
if err := core.Initialize(); err != nil {
c.Ui.Error(fmt.Sprintf("Initialization error, continuing: %v", err))
}
tpl := core.Template
// Output variables section
variables := []*template.Variable{}
{
// sort variables to avoid map's randomness
for _, variable := range tpl.Variables {
variables = append(variables, variable)
}
sort.Slice(variables, func(i, j int) bool {
return variables[i].Key < variables[j].Key
})
}
for _, variable := range variables {
variablesContent := hclwrite.NewEmptyFile()
variablesBody := variablesContent.Body()
variableBody := variablesBody.AppendNewBlock("variable", []string{variable.Key}).Body()
variableBody.SetAttributeRaw("type", hclwrite.Tokens{&hclwrite.Token{Bytes: []byte("string")}})
if variable.Default != "" || !variable.Required {
variableBody.SetAttributeValue("default", hcl2shim.HCL2ValueFromConfigValue(variable.Default))
}
if isSensitiveVariable(variable.Key, tpl.SensitiveVariables) {
variableBody.SetAttributeValue("sensitive", cty.BoolVal(true))
}
variablesBody.AppendNewline()
out.Write(transposeTemplatingCalls(variablesContent.Bytes()))
}
fmt.Fprintln(out, `# "timestamp" template function replacement`)
fmt.Fprintln(out, `locals { timestamp = regex_replace(timestamp(), "[- TZ:]", "") }`)
// Output sources section
builders := []*template.Builder{}
{
// sort builders to avoid map's randomnes
for _, builder := range tpl.Builders {
builders = append(builders, builder)
}
sort.Slice(builders, func(i, j int) bool {
return builders[i].Type+builders[i].Name < builders[j].Type+builders[j].Name
})
}
out.Write([]byte(sourcesHeader))
for i, builderCfg := range builders {
sourcesContent := hclwrite.NewEmptyFile()
body := sourcesContent.Body()
body.AppendNewline()
if !c.Meta.CoreConfig.Components.BuilderStore.Has(builderCfg.Type) {
c.Ui.Error(fmt.Sprintf("unknown builder type: %q\n", builderCfg.Type))
return 1
}
if builderCfg.Name == "" || builderCfg.Name == builderCfg.Type {
builderCfg.Name = fmt.Sprintf("autogenerated_%d", i+1)
}
sourceBody := body.AppendNewBlock("source", []string{builderCfg.Type, builderCfg.Name}).Body()
jsonBodyToHCL2Body(sourceBody, builderCfg.Config)
_, _ = out.Write(transposeTemplatingCalls(sourcesContent.Bytes()))
}
// Output build section
out.Write([]byte(buildHeader))
buildContent := hclwrite.NewEmptyFile()
buildBody := buildContent.Body()
if tpl.Description != "" {
buildBody.SetAttributeValue("description", cty.StringVal(tpl.Description))
buildBody.AppendNewline()
}
sourceNames := []string{}
for _, builder := range builders {
sourceNames = append(sourceNames, fmt.Sprintf("source.%s.%s", builder.Type, builder.Name))
}
buildBody.SetAttributeValue("sources", hcl2shim.HCL2ValueFromConfigValue(sourceNames))
buildBody.AppendNewline()
_, _ = buildContent.WriteTo(out)
for _, provisioner := range tpl.Provisioners {
provisionerContent := hclwrite.NewEmptyFile()
body := provisionerContent.Body()
buildBody.AppendNewline()
block := body.AppendNewBlock("provisioner", []string{provisioner.Type})
cfg := provisioner.Config
if len(provisioner.Except) > 0 {
cfg["except"] = provisioner.Except
}
if len(provisioner.Only) > 0 {
cfg["only"] = provisioner.Only
}
if provisioner.MaxRetries != "" {
cfg["max_retries"] = provisioner.MaxRetries
}
if provisioner.Timeout > 0 {
cfg["timeout"] = provisioner.Timeout.String()
}
jsonBodyToHCL2Body(block.Body(), cfg)
out.Write(transposeTemplatingCalls(provisionerContent.Bytes()))
}
for _, pps := range tpl.PostProcessors {
postProcessorContent := hclwrite.NewEmptyFile()
body := postProcessorContent.Body()
switch len(pps) {
case 0:
continue
case 1:
default:
body = body.AppendNewBlock("post-processors", nil).Body()
}
for _, pp := range pps {
ppBody := body.AppendNewBlock("post-processor", []string{pp.Type}).Body()
if pp.KeepInputArtifact != nil {
ppBody.SetAttributeValue("keep_input_artifact", cty.BoolVal(*pp.KeepInputArtifact))
}
cfg := pp.Config
if len(pp.Except) > 0 {
cfg["except"] = pp.Except
}
if len(pp.Only) > 0 {
cfg["only"] = pp.Only
}
if pp.Name != "" && pp.Name != pp.Type {
cfg["name"] = pp.Name
}
jsonBodyToHCL2Body(ppBody, cfg)
}
_, _ = out.Write(transposeTemplatingCalls(postProcessorContent.Bytes()))
}
_, _ = out.Write([]byte("}\n"))
_, _ = output.Write(hclwrite.Format(out.Bytes()))
c.Ui.Say(fmt.Sprintf("Successfully created %s ", cla.OutputFile))
return 0
}
// transposeTemplatingCalls executes parts of blocks as go template files and replaces
// their result with their hcl2 variant. If something goes wrong the template
// containing the go template string is returned.
func transposeTemplatingCalls(s []byte) []byte {
fallbackReturn := func(err error) []byte {
return append([]byte(fmt.Sprintf("\n#could not parse template for following block: %q\n", err)), s...)
}
funcMap := texttemplate.FuncMap{
"timestamp": func() string {
return "${local.timestamp}"
},
"isotime": func() string {
return "${local.timestamp}"
},
"user": func(in string) string {
return fmt.Sprintf("${var.%s}", in)
},
"env": func(in string) string {
return fmt.Sprintf("${var.%s}", in)
},
"build": func(a string) string {
return fmt.Sprintf("${build.%s}", a)
},
}
tpl, err := texttemplate.New("generated").
Funcs(funcMap).
Parse(string(s))
if err != nil {
return fallbackReturn(err)
}
str := &bytes.Buffer{}
v := struct {
HTTPIP string
HTTPPort string
}{
HTTPIP: "{{ .HTTPIP }}",
HTTPPort: "{{ .HTTPPort }}",
}
if err := tpl.Execute(str, v); err != nil {
return fallbackReturn(err)
}
return str.Bytes()
}
func jsonBodyToHCL2Body(out *hclwrite.Body, kvs map[string]interface{}) {
ks := []string{}
for k := range kvs {
ks = append(ks, k)
}
sort.Strings(ks)
for _, k := range ks {
value := kvs[k]
switch value := value.(type) {
case map[string]interface{}:
var mostComplexElem interface{}
for _, randomElem := range value {
// HACK: we take the most complex element of that map because
// in HCL2, map of objects can be bodies, for example:
// map containing object: source_ami_filter {} ( body )
// simple string/string map: tags = {} ) ( attribute )
//
// if we could not find an object in this map then it's most
// likely a plain map and so we guess it should be and
// attribute. Though now if value refers to something that is
// an object but only contains a string or a bool; we could
// generate a faulty object. For example a (somewhat invalid)
// source_ami_filter where only `most_recent` is set.
switch randomElem.(type) {
case string, int, float64, bool:
if mostComplexElem != nil {
continue
}
mostComplexElem = randomElem
default:
mostComplexElem = randomElem
}
}
switch mostComplexElem.(type) {
case string, int, float64, bool:
out.SetAttributeValue(k, hcl2shim.HCL2ValueFromConfigValue(value))
default:
nestedBlockBody := out.AppendNewBlock(k, nil).Body()
jsonBodyToHCL2Body(nestedBlockBody, value)
}
case map[string]string, map[string]int, map[string]float64:
out.SetAttributeValue(k, hcl2shim.HCL2ValueFromConfigValue(value))
case []interface{}:
if len(value) == 0 {
continue
}
var mostComplexElem interface{}
for _, randomElem := range value {
// HACK: we take the most complex element of that slice because
// in hcl2 slices of plain types can be arrays, for example:
// simple string type: owners = ["0000000000"]
// object: launch_block_device_mappings {}
switch randomElem.(type) {
case string, int, float64, bool:
if mostComplexElem != nil {
continue
}
mostComplexElem = randomElem
default:
mostComplexElem = randomElem
}
}
switch mostComplexElem.(type) {
case map[string]interface{}:
// this is an object in a slice; so we unwrap it. We
// could try to remove any 's' suffix in the key, but
// this might not work everywhere.
for i := range value {
value := value[i].(map[string]interface{})
nestedBlockBody := out.AppendNewBlock(k, nil).Body()
jsonBodyToHCL2Body(nestedBlockBody, value)
}
continue
default:
out.SetAttributeValue(k, hcl2shim.HCL2ValueFromConfigValue(value))
}
default:
out.SetAttributeValue(k, hcl2shim.HCL2ValueFromConfigValue(value))
}
}
}
func isSensitiveVariable(key string, vars []*template.Variable) bool {
for _, v := range vars {
if v.Key == key {
return true
}
}
return false
}
func (*HCL2UpgradeCommand) Help() string {
helpText := `
Usage: packer hcl2_upgrade -output-file=JSON_TEMPLATE.pkr.hcl JSON_TEMPLATE...
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Will transform your JSON template into an HCL2 configuration.
`
return strings.TrimSpace(helpText)
}
func (*HCL2UpgradeCommand) Synopsis() string {
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return "transform a JSON template into an HCL2 configuration"
}
func (*HCL2UpgradeCommand) AutocompleteArgs() complete.Predictor {
return complete.PredictNothing
}
func (*HCL2UpgradeCommand) AutocompleteFlags() complete.Flags {
return complete.Flags{}
}