feat: add DAG core functions — parse, validate, topo sort, resolve env, cron match (0007a, 0007d)

Pure functions for parsing dagu-compatible YAML, validating DAG structure, topological sorting with parallel levels (Kahn's algorithm), and env variable resolution. Also adds cron_match for schedule matching. Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
2026-04-12 13:05:05 +02:00
parent cb96e85b69
commit c3dfc9315f
21 changed files with 1569 additions and 0 deletions
@@ -0,0 +1,12 @@
 package core
 import "time"
 // CronMatch returns true if time t matches all fields of the cron schedule.
 func CronMatch(sched CronSchedule, t time.Time) bool {
 	return intIn(t.Minute(), sched.Minute) &&
 		intIn(t.Hour(), sched.Hour) &&
 		intIn(t.Day(), sched.DayOfMonth) &&
 		intIn(int(t.Month()), sched.Month) &&
 		intIn(int(t.Weekday()), sched.DayOfWeek)
 }
@@ -0,0 +1,49 @@
 ---
 name: cron_match
 kind: function
 lang: go
 domain: core
 version: "1.0.0"
 purity: pure
 signature: "func CronMatch(sched CronSchedule, t time.Time) bool"
 description: "Verifica si un instante de tiempo coincide con un cron schedule. Compara los 5 campos (minuto, hora, dia del mes, mes, dia de la semana) y retorna true si todos coinciden."
 tags: [cron, scheduling, matching, time, pure]
 uses_functions: []
 uses_types: [cron_schedule_go_core]
 returns: []
 returns_optional: false
 error_type: ""
 imports: [time]
 params:
  - name: sched
    desc: "CronSchedule con listas de valores validos por campo (resultado de ParseCronExpr)"
  - name: t
    desc: "instante de tiempo a verificar contra el schedule"
 output: "true si t coincide con todos los campos del cron schedule"
 tested: true
 tests:
  - "9:00 AM coincide con 0 9 * * *"
  - "9:15 AM NO coincide con 0 9 * * *"
  - "lunes a las 9 coincide con 0 9 * * 1"
  - "domingo a las 9 NO coincide con 0 9 * * 1"
  - "wildcard * coincide con cualquier valor"
  - "specific month"
 test_file_path: "functions/core/cron_match_test.go"
 file_path: "functions/core/cron_match.go"
 ---
 ## Ejemplo
 ```go
 sched, _ := ParseCronExpr("0 9 * * *")
 t := time.Date(2026, 4, 11, 9, 0, 0, 0, time.UTC)
 CronMatch(sched, t) // true
 t2 := time.Date(2026, 4, 11, 10, 0, 0, 0, time.UTC)
 CronMatch(sched, t2) // false
 ```
 ## Notas
 Funcion pura. Usa AND semantics para day_of_month y day_of_week (ambos deben coincidir), igual que NextCronTime en el mismo paquete.
 Reutiliza el helper intIn definido en next_cron_time.go (mismo paquete core).
@@ -0,0 +1,88 @@
 package core
 import (
 	"testing"
 	"time"
 )
 func TestCronMatch(t *testing.T) {
 	t.Run("9:00 AM coincide con 0 9 * * *", func(t *testing.T) {
 		sched, err := ParseCronExpr("0 9 * * *")
 		if err != nil {
 			t.Fatalf("ParseCronExpr: %v", err)
 		}
 		ts := time.Date(2026, 4, 11, 9, 0, 0, 0, time.UTC)
 		if !CronMatch(sched, ts) {
 			t.Errorf("expected match for 9:00 AM with '0 9 * * *'")
 		}
 	})
 	t.Run("9:15 AM NO coincide con 0 9 * * *", func(t *testing.T) {
 		sched, err := ParseCronExpr("0 9 * * *")
 		if err != nil {
 			t.Fatalf("ParseCronExpr: %v", err)
 		}
 		ts := time.Date(2026, 4, 11, 9, 15, 0, 0, time.UTC)
 		if CronMatch(sched, ts) {
 			t.Errorf("expected no match for 9:15 AM with '0 9 * * *'")
 		}
 	})
 	t.Run("lunes a las 9 coincide con 0 9 * * 1", func(t *testing.T) {
 		sched, err := ParseCronExpr("0 9 * * 1")
 		if err != nil {
 			t.Fatalf("ParseCronExpr: %v", err)
 		}
 		// 2026-04-13 is a Monday
 		ts := time.Date(2026, 4, 13, 9, 0, 0, 0, time.UTC)
 		if !CronMatch(sched, ts) {
 			t.Errorf("expected match for Monday 9:00 with '0 9 * * 1'")
 		}
 	})
 	t.Run("domingo a las 9 NO coincide con 0 9 * * 1", func(t *testing.T) {
 		sched, err := ParseCronExpr("0 9 * * 1")
 		if err != nil {
 			t.Fatalf("ParseCronExpr: %v", err)
 		}
 		// 2026-04-12 is a Sunday (weekday 0)
 		ts := time.Date(2026, 4, 12, 9, 0, 0, 0, time.UTC)
 		if CronMatch(sched, ts) {
 			t.Errorf("expected no match for Sunday 9:00 with '0 9 * * 1'")
 		}
 	})
 	t.Run("wildcard * coincide con cualquier valor", func(t *testing.T) {
 		sched, err := ParseCronExpr("*/15 * * * *")
 		if err != nil {
 			t.Fatalf("ParseCronExpr: %v", err)
 		}
 		// 9:30 should match */15 (0,15,30,45)
 		ts := time.Date(2026, 4, 11, 9, 30, 0, 0, time.UTC)
 		if !CronMatch(sched, ts) {
 			t.Errorf("expected match for 9:30 with '*/15 * * * *'")
 		}
 		// 9:07 should NOT match */15
 		ts2 := time.Date(2026, 4, 11, 9, 7, 0, 0, time.UTC)
 		if CronMatch(sched, ts2) {
 			t.Errorf("expected no match for 9:07 with '*/15 * * * *'")
 		}
 	})
 	t.Run("specific month", func(t *testing.T) {
 		sched, err := ParseCronExpr("0 0 1 4 *")
 		if err != nil {
 			t.Fatalf("ParseCronExpr: %v", err)
 		}
 		// April 1st matches
 		ts := time.Date(2026, 4, 1, 0, 0, 0, 0, time.UTC)
 		if !CronMatch(sched, ts) {
 			t.Errorf("expected match for April 1 with '0 0 1 4 *'")
 		}
 		// March 1st does NOT match
 		ts2 := time.Date(2026, 3, 1, 0, 0, 0, 0, time.UTC)
 		if CronMatch(sched, ts2) {
 			t.Errorf("expected no match for March 1 with '0 0 1 4 *'")
 		}
 	})
 }
@@ -0,0 +1,65 @@
 package core
 // DagContinueOn controls whether a step continues on failure/skip.
 type DagContinueOn struct {
 	Failure bool
 	Skipped bool
 }
 // DagRetryPolicy configures automatic retries for a step.
 type DagRetryPolicy struct {
 	Limit       int
 	IntervalSec int
 }
 // DagStep represents a single step in a DAG workflow.
 type DagStep struct {
 	Name        string
 	ID          string
 	Description string
 	Command     string
 	Script      string
 	Args        []string
 	Shell       string
 	Dir         string
 	Depends     []string
 	Env         map[string]string
 	ContinueOn  DagContinueOn
 	RetryPolicy DagRetryPolicy
 	TimeoutSec  int
 	Output      string
 	Tags        []string
 }
 // DagHandlers contains lifecycle handler steps.
 type DagHandlers struct {
 	Init    []DagStep
 	Success []DagStep
 	Failure []DagStep
 	Exit    []DagStep
 }
 // DagDefinition is a complete DAG workflow parsed from YAML.
 type DagDefinition struct {
 	Name        string
 	Description string
 	Group       string
 	Type        string // "graph" or "" (chain/sequential)
 	WorkingDir  string
 	Shell       string
 	Env         map[string]string
 	Schedule    []string
 	Steps       []DagStep
 	HandlerOn   DagHandlers
 	Tags        []string
 	TimeoutSec  int
 	FilePath    string
 }
 // DagValidationResult contains validation output.
 type DagValidationResult struct {
 	Valid    bool
 	Errors   []string
 	Warnings []string
 	Levels   [][]string // topological levels (step names/IDs)
 }
@@ -0,0 +1,281 @@
 package core
 import (
 	"fmt"
 	"strings"
 	"gopkg.in/yaml.v3"
 )
 // rawDagStep is the loosely-typed intermediate representation of a DAG step.
 type rawDagStep struct {
 	Name        string            `yaml:"name"`
 	ID          string            `yaml:"id"`
 	Description string            `yaml:"description"`
 	Command     string            `yaml:"command"`
 	Script      string            `yaml:"script"`
 	Args        []string          `yaml:"args"`
 	Shell       string            `yaml:"shell"`
 	Dir         string            `yaml:"dir"`
 	WorkingDir  string            `yaml:"working_dir"`
 	Depends     []string          `yaml:"depends"`
 	Env         interface{}       `yaml:"env"`
 	ContinueOn  rawDagContinueOn  `yaml:"continue_on"`
 	RetryPolicy rawDagRetryPolicy `yaml:"retry_policy"`
 	TimeoutSec  int               `yaml:"timeout_sec"`
 	Output      string            `yaml:"output"`
 	Tags        []string          `yaml:"tags"`
 }
 type rawDagContinueOn struct {
 	Failure bool `yaml:"failure"`
 	Skipped bool `yaml:"skipped"`
 }
 type rawDagRetryPolicy struct {
 	Limit       int `yaml:"limit"`
 	IntervalSec int `yaml:"interval_sec"`
 }
 // rawDagHandlers handles both handler_on and handlers aliases.
 type rawDagHandlers struct {
 	Init    interface{} `yaml:"init"`
 	Success interface{} `yaml:"success"`
 	Failure interface{} `yaml:"failure"`
 	Exit    interface{} `yaml:"exit"`
 }
 // rawDag is the loosely-typed intermediate representation of a DAG YAML.
 type rawDag struct {
 	Name        string          `yaml:"name"`
 	Description string          `yaml:"description"`
 	Group       string          `yaml:"group"`
 	Type        string          `yaml:"type"`
 	WorkingDir  string          `yaml:"working_dir"`
 	Shell       string          `yaml:"shell"`
 	Env         interface{}     `yaml:"env"`
 	Schedule    interface{}     `yaml:"schedule"`
 	Steps       []rawDagStep    `yaml:"steps"`
 	HandlerOn   *rawDagHandlers `yaml:"handler_on"`
 	Handlers    *rawDagHandlers `yaml:"handlers"`
 	Tags        []string        `yaml:"tags"`
 	TimeoutSec  int             `yaml:"timeout_sec"`
 }
 // DagParse parses a YAML DAG definition compatible with Dagu format.
 // Handles schedule as string or list, env as list of single-key maps,
 // handler_on and handlers as aliases, and steps with command/script/depends.
 func DagParse(data []byte) (DagDefinition, error) {
 	var raw rawDag
 	if err := yaml.Unmarshal(data, &raw); err != nil {
 		return DagDefinition{}, fmt.Errorf("dag_parse: yaml unmarshal: %w", err)
 	}
 	def := DagDefinition{
 		Name:       raw.Name,
 		Description: raw.Description,
 		Group:      raw.Group,
 		Type:       raw.Type,
 		WorkingDir: raw.WorkingDir,
 		Shell:      raw.Shell,
 		Tags:       raw.Tags,
 		TimeoutSec: raw.TimeoutSec,
 	}
 	// Normalize env (list of single-key maps or plain map).
 	dagEnv, err := normalizeEnv(raw.Env)
 	if err != nil {
 		return DagDefinition{}, fmt.Errorf("dag_parse: env: %w", err)
 	}
 	def.Env = dagEnv
 	// Normalize schedule (string or list).
 	def.Schedule = normalizeSchedule(raw.Schedule)
 	// Normalize steps.
 	steps := make([]DagStep, 0, len(raw.Steps))
 	for i, rs := range raw.Steps {
 		step, err := normalizeStep(rs)
 		if err != nil {
 			return DagDefinition{}, fmt.Errorf("dag_parse: step[%d]: %w", i, err)
 		}
 		steps = append(steps, step)
 	}
 	def.Steps = steps
 	// Normalize handlers: handler_on takes precedence, fallback to handlers.
 	rawHandlers := raw.HandlerOn
 	if rawHandlers == nil {
 		rawHandlers = raw.Handlers
 	}
 	if rawHandlers != nil {
 		handlers, err := normalizeHandlers(rawHandlers)
 		if err != nil {
 			return DagDefinition{}, fmt.Errorf("dag_parse: handlers: %w", err)
 		}
 		def.HandlerOn = handlers
 	}
 	return def, nil
 }
 // normalizeSchedule converts schedule from string or []interface{} to []string.
 func normalizeSchedule(v interface{}) []string {
 	if v == nil {
 		return nil
 	}
 	switch t := v.(type) {
 	case string:
 		s := strings.TrimSpace(t)
 		if s == "" {
 			return nil
 		}
 		return []string{s}
 	case []interface{}:
 		result := make([]string, 0, len(t))
 		for _, item := range t {
 			if s, ok := item.(string); ok {
 				s = strings.TrimSpace(s)
 				if s != "" {
 					result = append(result, s)
 				}
 			}
 		}
 		return result
 	}
 	return nil
 }
 // normalizeEnv converts env from Dagu format (list of single-key maps) or plain map to map[string]string.
 func normalizeEnv(v interface{}) (map[string]string, error) {
 	if v == nil {
 		return nil, nil
 	}
 	switch t := v.(type) {
 	case map[string]interface{}:
 		// Plain YAML map.
 		result := make(map[string]string, len(t))
 		for k, val := range t {
 			result[k] = fmt.Sprintf("%v", val)
 		}
 		return result, nil
 	case []interface{}:
 		// Dagu format: list of single-key maps [KEY: value, KEY2: value2].
 		result := make(map[string]string)
 		for _, item := range t {
 			m, ok := item.(map[string]interface{})
 			if !ok {
 				continue
 			}
 			for k, val := range m {
 				result[k] = fmt.Sprintf("%v", val)
 			}
 		}
 		return result, nil
 	}
 	return nil, fmt.Errorf("unexpected env type %T", v)
 }
 // normalizeStep converts a rawDagStep to a DagStep.
 func normalizeStep(rs rawDagStep) (DagStep, error) {
 	stepEnv, err := normalizeEnv(rs.Env)
 	if err != nil {
 		return DagStep{}, fmt.Errorf("env: %w", err)
 	}
 	// working_dir is an alias for dir at the step level.
 	dir := rs.Dir
 	if dir == "" {
 		dir = rs.WorkingDir
 	}
 	return DagStep{
 		Name:        rs.Name,
 		ID:          rs.ID,
 		Description: rs.Description,
 		Command:     rs.Command,
 		Script:      rs.Script,
 		Args:        rs.Args,
 		Shell:       rs.Shell,
 		Dir:         dir,
 		Depends:     rs.Depends,
 		Env:         stepEnv,
 		ContinueOn: DagContinueOn{
 			Failure: rs.ContinueOn.Failure,
 			Skipped: rs.ContinueOn.Skipped,
 		},
 		RetryPolicy: DagRetryPolicy{
 			Limit:       rs.RetryPolicy.Limit,
 			IntervalSec: rs.RetryPolicy.IntervalSec,
 		},
 		TimeoutSec: rs.TimeoutSec,
 		Output:     rs.Output,
 		Tags:       rs.Tags,
 	}, nil
 }
 // normalizeHandlers converts rawDagHandlers to DagHandlers.
 // Each handler field can be a single step object or a list of steps.
 func normalizeHandlers(rh *rawDagHandlers) (DagHandlers, error) {
 	var h DagHandlers
 	var err error
 	h.Init, err = normalizeHandlerField(rh.Init)
 	if err != nil {
 		return DagHandlers{}, fmt.Errorf("init: %w", err)
 	}
 	h.Success, err = normalizeHandlerField(rh.Success)
 	if err != nil {
 		return DagHandlers{}, fmt.Errorf("success: %w", err)
 	}
 	h.Failure, err = normalizeHandlerField(rh.Failure)
 	if err != nil {
 		return DagHandlers{}, fmt.Errorf("failure: %w", err)
 	}
 	h.Exit, err = normalizeHandlerField(rh.Exit)
 	if err != nil {
 		return DagHandlers{}, fmt.Errorf("exit: %w", err)
 	}
 	return h, nil
 }
 // normalizeHandlerField converts a handler field (single step or list) to []DagStep.
 func normalizeHandlerField(v interface{}) ([]DagStep, error) {
 	if v == nil {
 		return nil, nil
 	}
 	// Re-marshal and unmarshal to handle polymorphic types cleanly.
 	b, err := yaml.Marshal(v)
 	if err != nil {
 		return nil, fmt.Errorf("re-marshal handler: %w", err)
 	}
 	// Try as a list first.
 	var rawList []rawDagStep
 	if err := yaml.Unmarshal(b, &rawList); err == nil && len(rawList) > 0 {
 		steps := make([]DagStep, 0, len(rawList))
 		for i, rs := range rawList {
 			step, err := normalizeStep(rs)
 			if err != nil {
 				return nil, fmt.Errorf("step[%d]: %w", i, err)
 			}
 			steps = append(steps, step)
 		}
 		return steps, nil
 	}
 	// Try as single step.
 	var rs rawDagStep
 	if err := yaml.Unmarshal(b, &rs); err != nil {
 		return nil, fmt.Errorf("unmarshal handler step: %w", err)
 	}
 	step, err := normalizeStep(rs)
 	if err != nil {
 		return nil, err
 	}
 	// If the step has no meaningful content, return nil.
 	if step.Name == "" && step.ID == "" && step.Command == "" && step.Script == "" {
 		return nil, nil
 	}
 	return []DagStep{step}, nil
 }
@@ -0,0 +1,54 @@
 ---
 name: dag_parse
 kind: function
 lang: go
 domain: core
 version: "1.0.0"
 purity: pure
 signature: "func DagParse(data []byte) (DagDefinition, error)"
 description: "Parsea YAML de definicion de DAG en formato compatible con Dagu. Soporta schedule como string o lista, env como lista de maps single-key (formato Dagu), handler_on y handlers como aliases, steps con command/script/depends/continue_on, y type graph."
 tags: [dag, yaml, parsing, workflow, dagu, pure]
 uses_functions: []
 uses_types: [dag_definition_go_core, dag_step_go_core, dag_handlers_go_core]
 returns: []
 returns_optional: false
 error_type: ""
 imports: [fmt, strings, gopkg.in/yaml.v3]
 params:
  - name: data
    desc: "contenido YAML de un archivo de definicion de DAG en formato Dagu"
 output: "DagDefinition con todos los campos normalizados; error si el YAML es sintaticamente invalido"
 tested: true
 tests:
  - "parsea DAG simple con steps y depends"
  - "parsea schedule como string y como lista"
  - "parsea env en formato lista de maps"
  - "parsea handler_on y handlers como alias"
  - "parsea continue_on y working_dir a nivel step"
  - "parsea type graph"
 test_file_path: "functions/core/dag_parse_test.go"
 file_path: "functions/core/dag_parse.go"
 ---
 ## Ejemplo
 ```go
 data := []byte(`
 name: mi-dag
 schedule: "0 9 * * *"
 steps:
  - name: hello
    command: echo "hello"
  - name: world
    command: echo "world"
    depends: [hello]
 `)
 dag, err := DagParse(data)
 // dag.Name = "mi-dag"
 // dag.Schedule = ["0 9 * * *"]
 // dag.Steps[1].Depends = ["hello"]
 ```
 ## Notas
 Funcion pura (el YAML es inmutable, no hay I/O). Internamente usa un struct rawDag para deserializar loosely y luego normaliza campos polimorficos. La estrategia de normalizacion: schedule string->[]string, env lista->map, handlers single-o-lista->[]DagStep. handler_on tiene precedencia sobre handlers si ambos estan presentes.
@@ -0,0 +1,213 @@
 package core
 import (
 	"testing"
 )
 func TestDagParse(t *testing.T) {
 	t.Run("parsea DAG simple con steps y depends", func(t *testing.T) {
 		data := []byte(`
 name: example
 description: Example workflow
 steps:
  - name: hello
    command: echo "Hello!"
  - name: list_files
    command: ls -la /tmp
    depends:
      - hello
 `)
 		dag, err := DagParse(data)
 		if err != nil {
 			t.Fatalf("unexpected error: %v", err)
 		}
 		if dag.Name != "example" {
 			t.Errorf("Name: got %q, want %q", dag.Name, "example")
 		}
 		if len(dag.Steps) != 2 {
 			t.Fatalf("Steps: got %d, want 2", len(dag.Steps))
 		}
 		if dag.Steps[0].Name != "hello" {
 			t.Errorf("Steps[0].Name: got %q, want %q", dag.Steps[0].Name, "hello")
 		}
 		if dag.Steps[1].Name != "list_files" {
 			t.Errorf("Steps[1].Name: got %q, want %q", dag.Steps[1].Name, "list_files")
 		}
 		if len(dag.Steps[1].Depends) != 1 || dag.Steps[1].Depends[0] != "hello" {
 			t.Errorf("Steps[1].Depends: got %v, want [hello]", dag.Steps[1].Depends)
 		}
 	})
 	t.Run("parsea schedule como string y como lista", func(t *testing.T) {
 		// Schedule as string.
 		dataStr := []byte(`
 name: dag-string-schedule
 schedule: "0 9 * * 5"
 steps:
  - name: step1
    command: echo ok
 `)
 		dagStr, err := DagParse(dataStr)
 		if err != nil {
 			t.Fatalf("unexpected error: %v", err)
 		}
 		if len(dagStr.Schedule) != 1 || dagStr.Schedule[0] != "0 9 * * 5" {
 			t.Errorf("Schedule (string): got %v, want [\"0 9 * * 5\"]", dagStr.Schedule)
 		}
 		// Schedule as list.
 		dataList := []byte(`
 name: dag-list-schedule
 schedule:
  - "0 9 * * *"
  - "0 18 * * *"
 steps:
  - name: step1
    command: echo ok
 `)
 		dagList, err := DagParse(dataList)
 		if err != nil {
 			t.Fatalf("unexpected error: %v", err)
 		}
 		if len(dagList.Schedule) != 2 {
 			t.Fatalf("Schedule (list): got %d items, want 2", len(dagList.Schedule))
 		}
 		if dagList.Schedule[0] != "0 9 * * *" {
 			t.Errorf("Schedule[0]: got %q, want %q", dagList.Schedule[0], "0 9 * * *")
 		}
 		if dagList.Schedule[1] != "0 18 * * *" {
 			t.Errorf("Schedule[1]: got %q, want %q", dagList.Schedule[1], "0 18 * * *")
 		}
 	})
 	t.Run("parsea env en formato lista de maps", func(t *testing.T) {
 		data := []byte(`
 name: dag-env
 env:
  - PROJECT_DIR: /home/lucas/analysis
  - PYTHON: /home/lucas/.venv/bin/python
 steps:
  - name: step1
    command: echo ${PROJECT_DIR}
 `)
 		dag, err := DagParse(data)
 		if err != nil {
 			t.Fatalf("unexpected error: %v", err)
 		}
 		if dag.Env["PROJECT_DIR"] != "/home/lucas/analysis" {
 			t.Errorf("Env[PROJECT_DIR]: got %q, want %q", dag.Env["PROJECT_DIR"], "/home/lucas/analysis")
 		}
 		if dag.Env["PYTHON"] != "/home/lucas/.venv/bin/python" {
 			t.Errorf("Env[PYTHON]: got %q, want %q", dag.Env["PYTHON"], "/home/lucas/.venv/bin/python")
 		}
 	})
 	t.Run("parsea handler_on y handlers como alias", func(t *testing.T) {
 		// handler_on with single step object.
 		dataHandlerOn := []byte(`
 name: dag-handler-on
 handler_on:
  failure:
    command: echo "FALLO"
 steps:
  - name: step1
    command: echo hello
 `)
 		dagHO, err := DagParse(dataHandlerOn)
 		if err != nil {
 			t.Fatalf("unexpected error (handler_on): %v", err)
 		}
 		if len(dagHO.HandlerOn.Failure) != 1 {
 			t.Fatalf("HandlerOn.Failure: got %d steps, want 1", len(dagHO.HandlerOn.Failure))
 		}
 		if dagHO.HandlerOn.Failure[0].Command != `echo "FALLO"` {
 			t.Errorf("HandlerOn.Failure[0].Command: got %q", dagHO.HandlerOn.Failure[0].Command)
 		}
 		// handlers alias with list of steps.
 		dataHandlers := []byte(`
 name: dag-handlers
 handlers:
  failure:
    - name: mark_as_failed
      command: echo "FAILED"
  success:
    - name: notify
      command: echo "OK"
 steps:
  - name: step1
    command: echo hello
 `)
 		dagH, err := DagParse(dataHandlers)
 		if err != nil {
 			t.Fatalf("unexpected error (handlers): %v", err)
 		}
 		if len(dagH.HandlerOn.Failure) != 1 || dagH.HandlerOn.Failure[0].Name != "mark_as_failed" {
 			t.Errorf("HandlerOn.Failure: got %v", dagH.HandlerOn.Failure)
 		}
 		if len(dagH.HandlerOn.Success) != 1 || dagH.HandlerOn.Success[0].Name != "notify" {
 			t.Errorf("HandlerOn.Success: got %v", dagH.HandlerOn.Success)
 		}
 	})
 	t.Run("parsea continue_on y working_dir a nivel step", func(t *testing.T) {
 		data := []byte(`
 name: dag-step-options
 steps:
  - id: ingest
    description: Procesar archivos
    working_dir: /home/lucas/project
    command: ./bin/ingest
    continue_on:
      failure: true
  - id: informe
    command: python /tmp/script.py
    depends: [ingest]
 `)
 		dag, err := DagParse(data)
 		if err != nil {
 			t.Fatalf("unexpected error: %v", err)
 		}
 		if len(dag.Steps) != 2 {
 			t.Fatalf("Steps: got %d, want 2", len(dag.Steps))
 		}
 		step0 := dag.Steps[0]
 		if step0.ID != "ingest" {
 			t.Errorf("Steps[0].ID: got %q, want %q", step0.ID, "ingest")
 		}
 		if step0.Dir != "/home/lucas/project" {
 			t.Errorf("Steps[0].Dir: got %q, want %q", step0.Dir, "/home/lucas/project")
 		}
 		if !step0.ContinueOn.Failure {
 			t.Errorf("Steps[0].ContinueOn.Failure: got false, want true")
 		}
 		step1 := dag.Steps[1]
 		if len(step1.Depends) != 1 || step1.Depends[0] != "ingest" {
 			t.Errorf("Steps[1].Depends: got %v, want [ingest]", step1.Depends)
 		}
 	})
 	t.Run("parsea type graph", func(t *testing.T) {
 		data := []byte(`
 name: dag-graph
 type: graph
 tags: [finanzas, semanal]
 steps:
  - name: step1
    command: echo a
  - name: step2
    command: echo b
    depends: [step1]
 `)
 		dag, err := DagParse(data)
 		if err != nil {
 			t.Fatalf("unexpected error: %v", err)
 		}
 		if dag.Type != "graph" {
 			t.Errorf("Type: got %q, want %q", dag.Type, "graph")
 		}
 		if len(dag.Tags) != 2 {
 			t.Errorf("Tags: got %v, want [finanzas semanal]", dag.Tags)
 		}
 	})
 }
@@ -0,0 +1,157 @@
 package core
 import (
 	"strings"
 )
 // DagResolveEnv resolves environment variable references in a DagDefinition.
 // It parses environ (KEY=VALUE pairs from os.Environ()), merges with dag.Env
 // (dag.Env takes precedence), and substitutes ${VAR} and $VAR in Command,
 // Script, Dir, Args, and Env values of each step. Also substitutes in
 // DagDefinition.WorkingDir. Returns a new DagDefinition without mutating the original.
 func DagResolveEnv(dag DagDefinition, environ []string) DagDefinition {
 	// Parse environ into a base map.
 	base := parseEnviron(environ)
 	// Merge dag.Env over base (dag.Env has precedence).
 	dagEnv := mergeMaps(base, dag.Env)
 	// Build new DagDefinition (shallow copy, then replace fields).
 	result := dag
 	// Substitute in WorkingDir.
 	result.WorkingDir = substitute(dag.WorkingDir, dagEnv)
 	// Substitute in Env values of the DAG itself.
 	result.Env = substituteMap(dag.Env, dagEnv)
 	// Resolve steps.
 	resolvedSteps := make([]DagStep, len(dag.Steps))
 	for i, step := range dag.Steps {
 		// Merge dag env with step env (step env has precedence).
 		stepEnv := mergeMaps(dagEnv, step.Env)
 		rs := step
 		rs.Command = substitute(step.Command, stepEnv)
 		rs.Script = substitute(step.Script, stepEnv)
 		rs.Dir = substitute(step.Dir, stepEnv)
 		if len(step.Args) > 0 {
 			args := make([]string, len(step.Args))
 			for j, arg := range step.Args {
 				args[j] = substitute(arg, stepEnv)
 			}
 			rs.Args = args
 		}
 		rs.Env = substituteMap(step.Env, stepEnv)
 		resolvedSteps[i] = rs
 	}
 	result.Steps = resolvedSteps
 	return result
 }
 // parseEnviron parses a slice of "KEY=VALUE" strings into a map.
 func parseEnviron(environ []string) map[string]string {
 	m := make(map[string]string, len(environ))
 	for _, kv := range environ {
 		idx := strings.IndexByte(kv, '=')
 		if idx < 0 {
 			continue
 		}
 		m[kv[:idx]] = kv[idx+1:]
 	}
 	return m
 }
 // mergeMaps returns a new map with all entries from base, then overlaid with overlay.
 func mergeMaps(base, overlay map[string]string) map[string]string {
 	result := make(map[string]string, len(base)+len(overlay))
 	for k, v := range base {
 		result[k] = v
 	}
 	for k, v := range overlay {
 		result[k] = v
 	}
 	return result
 }
 // substituteMap applies substitute to all values in a map.
 func substituteMap(m map[string]string, env map[string]string) map[string]string {
 	if len(m) == 0 {
 		return m
 	}
 	result := make(map[string]string, len(m))
 	for k, v := range m {
 		result[k] = substitute(v, env)
 	}
 	return result
 }
 // substitute replaces ${VAR} and $VAR occurrences in s using the env map.
 func substitute(s string, env map[string]string) string {
 	if s == "" || !strings.Contains(s, "$") {
 		return s
 	}
 	var b strings.Builder
 	i := 0
 	for i < len(s) {
 		if s[i] != '$' {
 			b.WriteByte(s[i])
 			i++
 			continue
 		}
 		// Found '$'
 		i++
 		if i >= len(s) {
 			b.WriteByte('$')
 			break
 		}
 		if s[i] == '{' {
 			// ${VAR} form.
 			i++
 			end := strings.IndexByte(s[i:], '}')
 			if end < 0 {
 				// No closing brace — write as-is.
 				b.WriteString("${")
 				continue
 			}
 			varName := s[i : i+end]
 			i += end + 1
 			if val, ok := env[varName]; ok {
 				b.WriteString(val)
 			} else {
 				b.WriteString("${")
 				b.WriteString(varName)
 				b.WriteByte('}')
 			}
 		} else if isEnvVarChar(s[i]) {
 			// $VAR form (bare variable name).
 			start := i
 			for i < len(s) && isEnvVarChar(s[i]) {
 				i++
 			}
 			varName := s[start:i]
 			if val, ok := env[varName]; ok {
 				b.WriteString(val)
 			} else {
 				b.WriteByte('$')
 				b.WriteString(varName)
 			}
 		} else {
 			// Not a valid variable start — keep '$' and continue.
 			b.WriteByte('$')
 		}
 	}
 	return b.String()
 }
 // isEnvVarChar returns true for characters valid in environment variable names.
 func isEnvVarChar(c byte) bool {
 	return (c >= 'A' && c <= 'Z') || (c >= 'a' && c <= 'z') || (c >= '0' && c <= '9') || c == '_'
 }
@@ -0,0 +1,39 @@
 ---
 name: dag_resolve_env
 kind: function
 lang: go
 domain: core
 version: "1.0.0"
 purity: pure
 signature: "func DagResolveEnv(dag DagDefinition, environ []string) DagDefinition"
 description: "Resuelve referencias a variables de entorno (${VAR} y $VAR) en un DagDefinition. Mergea environ del sistema con dag.Env (dag.Env tiene precedencia), y sustituye en Command, Script, Dir, Args y Env values de cada step. No muta el DagDefinition original."
 tags: [dag, env, substitution, variable-expansion, pure]
 uses_functions: []
 uses_types: [dag_definition_go_core, dag_step_go_core]
 returns: []
 returns_optional: false
 error_type: ""
 imports: [strings]
 params:
  - name: dag
    desc: "DagDefinition parseado con posibles referencias ${VAR} en sus campos"
  - name: environ
    desc: "lista de strings KEY=VALUE del entorno del sistema (tipicamente os.Environ())"
 output: "nuevo DagDefinition con todas las referencias de variables sustituidas por sus valores"
 tested: false
 tests: []
 test_file_path: ""
 file_path: "functions/core/dag_resolve_env.go"
 ---
 ## Ejemplo
 ```go
 dag, _ := DagParse(yamlData)
 resolved := DagResolveEnv(dag, os.Environ())
 // resolved.Steps[0].Command tiene ${PROJECT_DIR} sustituido
 ```
 ## Notas
 Funcion pura. No muta el DagDefinition de entrada — retorna una copia con los campos resueltos. Precedencia de variables: environ base < dag.Env < step.Env. Sustituye tanto ${VAR} (con llaves) como $VAR (bare). Si una variable no existe en el entorno, se deja sin sustituir. Los campos sustituidos son: DagDefinition.WorkingDir, Env values del DAG, y por step: Command, Script, Dir, Args, Env values.
@@ -0,0 +1,78 @@
 package core
 import "fmt"
 // DagTopoSort performs a topological sort of DAG steps using Kahn's algorithm.
 // Returns levels where each level contains steps that can run in parallel.
 // Returns an error if a dependency cycle is detected.
 func DagTopoSort(steps []DagStep) ([][]DagStep, error) {
 	if len(steps) == 0 {
 		return nil, nil
 	}
 	// Build index: ref -> DagStep.
 	index := make(map[string]DagStep, len(steps))
 	for _, s := range steps {
 		index[stepRef(s)] = s
 	}
 	// Compute in-degree for each step.
 	inDegree := make(map[string]int, len(steps))
 	for _, s := range steps {
 		ref := stepRef(s)
 		if _, ok := inDegree[ref]; !ok {
 			inDegree[ref] = 0
 		}
 		for range s.Depends {
 			inDegree[ref]++ // ref depends on a dep, so ref gets +1
 		}
 	}
 	// Build adjacency list: dep -> list of steps that depend on dep.
 	adj := make(map[string][]string, len(steps))
 	for _, s := range steps {
 		ref := stepRef(s)
 		for _, dep := range s.Depends {
 			adj[dep] = append(adj[dep], ref)
 		}
 	}
 	// Initialize queue with steps that have in-degree 0.
 	var queue []string
 	for _, s := range steps {
 		ref := stepRef(s)
 		if inDegree[ref] == 0 {
 			queue = append(queue, ref)
 		}
 	}
 	var levels [][]DagStep
 	processed := 0
 	for len(queue) > 0 {
 		// The current queue forms a parallel level.
 		level := make([]DagStep, 0, len(queue))
 		nextQueue := []string{}
 		for _, ref := range queue {
 			level = append(level, index[ref])
 			processed++
 			// Reduce in-degree for dependents.
 			for _, dependent := range adj[ref] {
 				inDegree[dependent]--
 				if inDegree[dependent] == 0 {
 					nextQueue = append(nextQueue, dependent)
 				}
 			}
 		}
 		levels = append(levels, level)
 		queue = nextQueue
 	}
 	if processed != len(steps) {
 		return nil, fmt.Errorf("dag_topo_sort: cycle detected (%d of %d steps processed)", processed, len(steps))
 	}
 	return levels, nil
 }
@@ -0,0 +1,48 @@
 ---
 name: dag_topo_sort
 kind: function
 lang: go
 domain: core
 version: "1.0.0"
 purity: pure
 signature: "func DagTopoSort(steps []DagStep) ([][]DagStep, error)"
 description: "Ordenamiento topologico de steps de un DAG usando el algoritmo de Kahn. Retorna niveles donde cada nivel contiene steps que pueden ejecutarse en paralelo. Detecta ciclos y retorna error si los hay."
 tags: [dag, topological-sort, graph, kahn, pure]
 uses_functions: []
 uses_types: [dag_step_go_core]
 returns: []
 returns_optional: false
 error_type: ""
 imports: [fmt]
 params:
  - name: steps
    desc: "lista de DagStep con sus dependencias definidas en el campo Depends"
 output: "slice de niveles donde cada nivel es un slice de DagStep que pueden ejecutarse en paralelo; error si hay ciclo"
 tested: true
 tests:
  - "cadena lineal A->B->C produce tres niveles"
  - "diamond A->B A->C B->D C->D produce cuatro niveles"
  - "steps paralelos sin depends produce un solo nivel"
  - "ciclo A->B->A retorna error"
 test_file_path: "functions/core/dag_topo_sort_test.go"
 file_path: "functions/core/dag_topo_sort.go"
 ---
 ## Ejemplo
 ```go
 steps := []DagStep{
    {Name: "a"},
    {Name: "b", Depends: []string{"a"}},
    {Name: "c", Depends: []string{"a"}},
    {Name: "d", Depends: []string{"b", "c"}},
 }
 levels, err := DagTopoSort(steps)
 // levels[0] = [a]
 // levels[1] = [b, c]   (paralelo)
 // levels[2] = [d]
 ```
 ## Notas
 Funcion pura. Implementa Kahn's algorithm: calcula in-degree inicial, pone en cola los steps con in-degree 0, extrae un nivel completo por iteracion y reduce el in-degree de los dependientes. Si al terminar hay steps sin procesar, hay un ciclo. El orden dentro de cada nivel no esta garantizado — depende del orden del slice de entrada.
@@ -0,0 +1,95 @@
 package core
 import (
 	"testing"
 )
 func TestDagTopoSort(t *testing.T) {
 	t.Run("cadena lineal A->B->C produce tres niveles", func(t *testing.T) {
 		steps := []DagStep{
 			{Name: "a"},
 			{Name: "b", Depends: []string{"a"}},
 			{Name: "c", Depends: []string{"b"}},
 		}
 		levels, err := DagTopoSort(steps)
 		if err != nil {
 			t.Fatalf("unexpected error: %v", err)
 		}
 		if len(levels) != 3 {
 			t.Fatalf("levels: got %d, want 3", len(levels))
 		}
 		if len(levels[0]) != 1 || levels[0][0].Name != "a" {
 			t.Errorf("levels[0]: got %v, want [a]", stepNames(levels[0]))
 		}
 		if len(levels[1]) != 1 || levels[1][0].Name != "b" {
 			t.Errorf("levels[1]: got %v, want [b]", stepNames(levels[1]))
 		}
 		if len(levels[2]) != 1 || levels[2][0].Name != "c" {
 			t.Errorf("levels[2]: got %v, want [c]", stepNames(levels[2]))
 		}
 	})
 	t.Run("diamond A->B A->C B->D C->D produce cuatro niveles", func(t *testing.T) {
 		steps := []DagStep{
 			{Name: "a"},
 			{Name: "b", Depends: []string{"a"}},
 			{Name: "c", Depends: []string{"a"}},
 			{Name: "d", Depends: []string{"b", "c"}},
 		}
 		levels, err := DagTopoSort(steps)
 		if err != nil {
 			t.Fatalf("unexpected error: %v", err)
 		}
 		// Expected: level0=[a], level1=[b,c], level2=[d]
 		if len(levels) != 3 {
 			t.Fatalf("levels: got %d, want 3", len(levels))
 		}
 		if len(levels[0]) != 1 || levels[0][0].Name != "a" {
 			t.Errorf("levels[0]: got %v, want [a]", stepNames(levels[0]))
 		}
 		if len(levels[1]) != 2 {
 			t.Errorf("levels[1]: got %v, want 2 steps", stepNames(levels[1]))
 		}
 		if len(levels[2]) != 1 || levels[2][0].Name != "d" {
 			t.Errorf("levels[2]: got %v, want [d]", stepNames(levels[2]))
 		}
 	})
 	t.Run("steps paralelos sin depends produce un solo nivel", func(t *testing.T) {
 		steps := []DagStep{
 			{Name: "x"},
 			{Name: "y"},
 			{Name: "z"},
 		}
 		levels, err := DagTopoSort(steps)
 		if err != nil {
 			t.Fatalf("unexpected error: %v", err)
 		}
 		if len(levels) != 1 {
 			t.Fatalf("levels: got %d, want 1", len(levels))
 		}
 		if len(levels[0]) != 3 {
 			t.Errorf("levels[0]: got %d steps, want 3", len(levels[0]))
 		}
 	})
 	t.Run("ciclo A->B->A retorna error", func(t *testing.T) {
 		steps := []DagStep{
 			{Name: "a", Depends: []string{"b"}},
 			{Name: "b", Depends: []string{"a"}},
 		}
 		_, err := DagTopoSort(steps)
 		if err == nil {
 			t.Fatal("expected error for cycle, got nil")
 		}
 	})
 }
 // stepNames extracts step names for readable test output.
 func stepNames(steps []DagStep) []string {
 	names := make([]string, len(steps))
 	for i, s := range steps {
 		names[i] = stepRef(s)
 	}
 	return names
 }
@@ -0,0 +1,83 @@
 package core
 import "fmt"
 // DagValidate validates a DagDefinition for structural correctness.
 // Checks: steps have name/ID, no duplicate names/IDs, all depends reference
 // existing steps, no dependency cycles. On success, computes topological levels.
 // Returns warnings for steps with both command and script set.
 func DagValidate(dag DagDefinition) DagValidationResult {
 	result := DagValidationResult{Valid: true}
 	// Build name/ID sets and check for missing identifiers and duplicates.
 	seen := make(map[string]bool)
 	for i, step := range dag.Steps {
 		ref := stepRef(step)
 		if ref == "" {
 			result.Errors = append(result.Errors,
 				fmt.Sprintf("step[%d]: must have name or id", i))
 			result.Valid = false
 			continue
 		}
 		if seen[ref] {
 			result.Errors = append(result.Errors,
 				fmt.Sprintf("step[%d]: duplicate name/id %q", i, ref))
 			result.Valid = false
 		}
 		seen[ref] = true
 		// Warning: command and script both set.
 		if step.Command != "" && step.Script != "" {
 			result.Warnings = append(result.Warnings,
 				fmt.Sprintf("step %q: has both command and script", ref))
 		}
 	}
 	if !result.Valid {
 		return result
 	}
 	// Check that all depends reference existing steps.
 	for _, step := range dag.Steps {
 		for _, dep := range step.Depends {
 			if !seen[dep] {
 				result.Errors = append(result.Errors,
 					fmt.Sprintf("step %q: depends on unknown step %q", stepRef(step), dep))
 				result.Valid = false
 			}
 		}
 	}
 	if !result.Valid {
 		return result
 	}
 	// Topological sort with Kahn's — detects cycles and computes levels.
 	levels, err := DagTopoSort(dag.Steps)
 	if err != nil {
 		result.Errors = append(result.Errors, fmt.Sprintf("cycle detected: %v", err))
 		result.Valid = false
 		return result
 	}
 	// Convert [][]DagStep to [][]string for the result.
 	strLevels := make([][]string, len(levels))
 	for i, level := range levels {
 		refs := make([]string, len(level))
 		for j, s := range level {
 			refs[j] = stepRef(s)
 		}
 		strLevels[i] = refs
 	}
 	result.Levels = strLevels
 	return result
 }
 // stepRef returns the canonical reference for a step (ID preferred, then Name).
 func stepRef(s DagStep) string {
 	if s.ID != "" {
 		return s.ID
 	}
 	return s.Name
 }
@@ -0,0 +1,46 @@
 ---
 name: dag_validate
 kind: function
 lang: go
 domain: core
 version: "1.0.0"
 purity: pure
 signature: "func DagValidate(dag DagDefinition) DagValidationResult"
 description: "Valida un DagDefinition para correcto uso estructural. Verifica que cada step tenga nombre o ID, que no haya duplicados, que todos los depends referencien steps existentes y que no haya ciclos (algoritmo de Kahn). Si el DAG es valido, calcula los niveles topologicos."
 tags: [dag, validation, workflow, graph, pure]
 uses_functions: [dag_topo_sort_go_core]
 uses_types: [dag_definition_go_core, dag_validation_result_go_core]
 returns: []
 returns_optional: false
 error_type: ""
 imports: [fmt]
 params:
  - name: dag
    desc: "DagDefinition parseado y a validar"
 output: "DagValidationResult con Valid=true si no hay errores, Errors con los problemas encontrados, Warnings con avisos no fatales, y Levels con los niveles topologicos si el DAG es valido"
 tested: true
 tests:
  - "DAG valido retorna Valid true y levels calculados"
  - "step sin nombre retorna error"
  - "depends a step inexistente retorna error"
  - "ciclo en dependencias retorna error"
 test_file_path: "functions/core/dag_validate_test.go"
 file_path: "functions/core/dag_validate.go"
 ---
 ## Ejemplo
 ```go
 dag, _ := DagParse(yamlData)
 res := DagValidate(dag)
 if !res.Valid {
    for _, e := range res.Errors {
        fmt.Println("ERROR:", e)
    }
 }
 // res.Levels = [["step-a"], ["step-b", "step-c"], ["step-d"]]
 ```
 ## Notas
 Funcion pura. No modifica el DagDefinition de entrada. El calculo de niveles topologicos se delega a DagTopoSort para mantener la separacion de responsabilidades. Un warning (command+script simultaneos) no invalida el DAG.
@@ -0,0 +1,113 @@
 package core
 import (
 	"testing"
 )
 func TestDagValidate(t *testing.T) {
 	t.Run("DAG valido retorna Valid true y levels calculados", func(t *testing.T) {
 		dag := DagDefinition{
 			Name: "valid-dag",
 			Steps: []DagStep{
 				{Name: "a", Command: "echo a"},
 				{Name: "b", Command: "echo b", Depends: []string{"a"}},
 				{Name: "c", Command: "echo c", Depends: []string{"a"}},
 				{Name: "d", Command: "echo d", Depends: []string{"b", "c"}},
 			},
 		}
 		res := DagValidate(dag)
 		if !res.Valid {
 			t.Errorf("Valid: got false, want true. Errors: %v", res.Errors)
 		}
 		if len(res.Errors) != 0 {
 			t.Errorf("Errors: got %v, want empty", res.Errors)
 		}
 		// Should have 3 levels: [a], [b,c], [d]
 		if len(res.Levels) != 3 {
 			t.Errorf("Levels: got %d, want 3. Levels: %v", len(res.Levels), res.Levels)
 		}
 		if len(res.Levels[0]) != 1 || res.Levels[0][0] != "a" {
 			t.Errorf("Levels[0]: got %v, want [a]", res.Levels[0])
 		}
 		if len(res.Levels[2]) != 1 || res.Levels[2][0] != "d" {
 			t.Errorf("Levels[2]: got %v, want [d]", res.Levels[2])
 		}
 	})
 	t.Run("step sin nombre retorna error", func(t *testing.T) {
 		dag := DagDefinition{
 			Name: "bad-dag",
 			Steps: []DagStep{
 				{Command: "echo hello"}, // no name, no ID
 			},
 		}
 		res := DagValidate(dag)
 		if res.Valid {
 			t.Error("Valid: got true, want false")
 		}
 		if len(res.Errors) == 0 {
 			t.Error("Errors: got empty, want at least one error")
 		}
 	})
 	t.Run("depends a step inexistente retorna error", func(t *testing.T) {
 		dag := DagDefinition{
 			Name: "bad-deps-dag",
 			Steps: []DagStep{
 				{Name: "step1", Command: "echo ok"},
 				{Name: "step2", Command: "echo ok", Depends: []string{"nonexistent"}},
 			},
 		}
 		res := DagValidate(dag)
 		if res.Valid {
 			t.Error("Valid: got true, want false")
 		}
 		found := false
 		for _, e := range res.Errors {
 			if containsStr(e, "nonexistent") {
 				found = true
 				break
 			}
 		}
 		if !found {
 			t.Errorf("Errors should mention 'nonexistent', got: %v", res.Errors)
 		}
 	})
 	t.Run("ciclo en dependencias retorna error", func(t *testing.T) {
 		dag := DagDefinition{
 			Name: "cyclic-dag",
 			Steps: []DagStep{
 				{Name: "a", Command: "echo a", Depends: []string{"b"}},
 				{Name: "b", Command: "echo b", Depends: []string{"a"}},
 			},
 		}
 		res := DagValidate(dag)
 		if res.Valid {
 			t.Error("Valid: got true, want false")
 		}
 		found := false
 		for _, e := range res.Errors {
 			if containsStr(e, "cycle") {
 				found = true
 				break
 			}
 		}
 		if !found {
 			t.Errorf("Errors should mention 'cycle', got: %v", res.Errors)
 		}
 	})
 }
 // containsStr returns true if s contains substr.
 func containsStr(s, substr string) bool {
 	return len(s) >= len(substr) && (s == substr || len(substr) == 0 ||
 		func() bool {
 			for i := 0; i <= len(s)-len(substr); i++ {
 				if s[i:i+len(substr)] == substr {
 					return true
 				}
 			}
 			return false
 		}())
 }
@@ -0,0 +1,20 @@
 ---
 name: dag_continue_on
 lang: go
 domain: core
 version: "1.0.0"
 algebraic: product
 definition: |
  type DagContinueOn struct {
      Failure bool
      Skipped bool
  }
 description: "Politica de continuacion de un step DAG ante fallos o saltos. Cuando Failure=true el DAG no se detiene si el step falla. Cuando Skipped=true tampoco se detiene si el step es saltado."
 tags: [dag, workflow, policy, error-handling]
 uses_types: []
 file_path: "functions/core/dag_definition.go"
 ---
 ## Notas
 Tipo producto. Embebido en DagStep. Corresponde al campo `continue_on` del YAML de Dagu.
@@ -0,0 +1,31 @@
 ---
 name: dag_definition
 lang: go
 domain: core
 version: "1.0.0"
 algebraic: product
 definition: |
  type DagDefinition struct {
      Name        string
      Description string
      Group       string
      Type        string
      WorkingDir  string
      Shell       string
      Env         map[string]string
      Schedule    []string
      Steps       []DagStep
      HandlerOn   DagHandlers
      Tags        []string
      TimeoutSec  int
      FilePath    string
  }
 description: "Definicion completa de un workflow DAG parseada desde YAML compatible con Dagu. Contiene steps, handlers de ciclo de vida, variables de entorno, schedule y metadatos del flujo."
 tags: [dag, workflow, yaml, dagu, definition]
 uses_types: [dag_step_go_core, dag_handlers_go_core]
 file_path: "functions/core/dag_definition.go"
 ---
 ## Notas
 Tipo producto. Type puede ser "graph" (ejecucion paralela por niveles topologicos) o vacio (cadena secuencial). Schedule es siempre una lista de strings (normalizado desde string o lista en el YAML). FilePath se rellena opcionalmente por el caller para saber el origen del archivo.
@@ -0,0 +1,22 @@
 ---
 name: dag_handlers
 lang: go
 domain: core
 version: "1.0.0"
 algebraic: product
 definition: |
  type DagHandlers struct {
      Init    []DagStep
      Success []DagStep
      Failure []DagStep
      Exit    []DagStep
  }
 description: "Handlers de ciclo de vida de un DAG. Cada campo contiene steps que se ejecutan en el evento correspondiente: inicializacion, exito, fallo o salida (siempre). Corresponde a handler_on o handlers en el YAML de Dagu."
 tags: [dag, workflow, handlers, lifecycle]
 uses_types: [dag_step_go_core]
 file_path: "functions/core/dag_definition.go"
 ---
 ## Notas
 Tipo producto. Embebido en DagDefinition. Los campos handler_on y handlers son aliases en el YAML de Dagu — ambos se normalizan a este tipo. Cada handler puede ser un step unico o una lista de steps en el YAML.
@@ -0,0 +1,20 @@
 ---
 name: dag_retry_policy
 lang: go
 domain: core
 version: "1.0.0"
 algebraic: product
 definition: |
  type DagRetryPolicy struct {
      Limit       int
      IntervalSec int
  }
 description: "Politica de reintentos automaticos para un step DAG. Limit es el numero maximo de reintentos e IntervalSec es el tiempo de espera entre intentos en segundos."
 tags: [dag, workflow, retry, policy]
 uses_types: []
 file_path: "functions/core/dag_definition.go"
 ---
 ## Notas
 Tipo producto. Embebido en DagStep. Corresponde al campo `retry_policy` del YAML de Dagu. Limit=0 significa sin reintentos.
@@ -0,0 +1,33 @@
 ---
 name: dag_step
 lang: go
 domain: core
 version: "1.0.0"
 algebraic: product
 definition: |
  type DagStep struct {
      Name        string
      ID          string
      Description string
      Command     string
      Script      string
      Args        []string
      Shell       string
      Dir         string
      Depends     []string
      Env         map[string]string
      ContinueOn  DagContinueOn
      RetryPolicy DagRetryPolicy
      TimeoutSec  int
      Output      string
      Tags        []string
  }
 description: "Un paso individual en un workflow DAG con command/script, dependencias y configuracion de reintentos. Soporta variables de entorno por step, directorio de trabajo propio y politica continue_on."
 tags: [dag, workflow, step, yaml, dagu]
 uses_types: [dag_continue_on_go_core, dag_retry_policy_go_core]
 file_path: "functions/core/dag_definition.go"
 ---
 ## Notas
 Tipo producto. El campo ID es opcional y se usa como referencia en otros steps (ej: `${id.stdout}`). Si Name e ID estan ambos vacios, el step es invalido. Env del step se mergea sobre el Env del DAG padre durante la resolucion.
@@ -0,0 +1,22 @@
 ---
 name: dag_validation_result
 lang: go
 domain: core
 version: "1.0.0"
 algebraic: product
 definition: |
  type DagValidationResult struct {
      Valid    bool
      Errors   []string
      Warnings []string
      Levels   [][]string
  }
 description: "Resultado de validar un DagDefinition. Contiene errores estructurales (ciclos, depends invalidos, nombres duplicados), warnings (command+script simultaneos) y los niveles topologicos calculados si el DAG es valido."
 tags: [dag, validation, workflow, result]
 uses_types: []
 file_path: "functions/core/dag_definition.go"
 ---
 ## Notas
 Tipo producto. Levels solo se rellena cuando Valid=true. Cada sub-slice de Levels contiene los nombres/IDs de steps que pueden ejecutarse en paralelo. El orden de Levels refleja el orden topologico del grafo de dependencias.