OpsLog/internal/award/award.go

// Package award computes amateur-radio award progress (worked / confirmed)
// directly from the logbook. An award is defined declaratively: a QSO FIELD to
// scan plus an optional regular-expression PATTERN that extracts the reference
// from that field. With no pattern the whole field value is the reference; with
// a pattern, capture group 1 (or the whole match) is the reference and a single
// QSO may yield several references (e.g. a Note holding "D74 D73").
//
// Examples:
//   DXCC : field "dxcc"   (no pattern)            → entity number
//   WAS  : field "state", DXCCFilter [291,110,6]  → US state
//   DDFM : field "note",  pattern "D(\d{1,2}[AB]?)" → French department from notes
//   WPX  : field "prefix" (computed from callsign)
package award

import (
	"regexp"
	"sort"
	"strconv"
	"strings"

	"hamlog/internal/qso"
)

// AwardType selects how a QSO is matched to an award's references.
//
//	"DXCC"      — match the QSO's DXCC entity number (references keyed by entity)
//	"QSOFIELDS" — search a QSO field for a reference code/description/pattern
//	"REFERENCE" — the reference is carried by a dedicated field (POTA_REF, …) or
//	              the per-reference DXCC list (e.g. RAC provinces by state)
//	"GRID"      — match a Maidenhead grid square
type AwardType = string

const (
	TypeDXCC      AwardType = "DXCC"
	TypeQSOFields AwardType = "QSOFIELDS"
	TypeReference AwardType = "REFERENCE"
	TypeGrid      AwardType = "GRID"
)

// Def defines one award. Fields mirror Log4OM's Award Management model: an
// identity + scope (when the award applies) + a matching rule (how a QSO maps
// to a reference) + confirmation rules. Most fields are optional; the zero
// value of a legacy Def (only Field/Pattern/DXCCFilter/Confirm/Total set) still
// behaves as before.
type Def struct {
	// --- Identity ---
	Code        string `json:"code"`                  // unique key, e.g. "DXCC"
	Name        string `json:"name"`                  // friendly name
	Description string `json:"description,omitempty"`  // free text
	Valid       bool   `json:"valid"`                 // award enabled
	Protected   bool   `json:"protected,omitempty"`   // shipped/locked award
	URL         string `json:"url,omitempty"`         // award home page
	DownloadURL string `json:"download_url,omitempty"` // reference-list source
	RefURL      string `json:"ref_url,omitempty"`     // per-ref link, <REF> placeholder
	ValidFrom   string `json:"valid_from,omitempty"`  // ISO date (QSOs before don't count)
	ValidTo     string `json:"valid_to,omitempty"`    // ISO date (QSOs after don't count)
	Alias       string `json:"alias,omitempty"`

	// --- Type & matching ---
	Type         AwardType `json:"type,omitempty"`          // matching strategy (default QSOFIELDS)
	Field        string    `json:"field"`                   // QSO field to scan (see fieldRaw)
	MatchBy      string    `json:"match_by,omitempty"`      // "code" | "description" | "pattern"
	ExactMatch   bool      `json:"exact_match,omitempty"`   // match the whole field vs substring
	Pattern      string    `json:"pattern"`                 // award-level Go regexp; group 1 = reference
	LeadingStr   string    `json:"leading_str,omitempty"`   // strip this prefix before matching
	TrailingStr  string    `json:"trailing_str,omitempty"`  // strip this suffix before matching
	Multi        bool      `json:"multi,omitempty"`         // a QSO may count for several references
	Dynamic      bool      `json:"dynamic,omitempty"`       // references not predefined (any value counts)
	AddPrefixes  []string  `json:"add_prefixes,omitempty"`  // possible reference additional prefixes

	// --- Scope ---
	DXCCFilter []int    `json:"dxcc_filter"`          // limit to these DXCC entities (nil = any)
	ValidBands []string `json:"valid_bands,omitempty"` // empty = all bands
	ValidModes []string `json:"valid_modes,omitempty"` // empty = all modes
	Emission   []string `json:"emission,omitempty"`    // CW | DIGITAL | PHONE (empty = all)

	// --- Confirmation ---
	Confirm             []string `json:"confirm"`                          // worked-confirmed: lotw|qsl|eqsl|qrzcom|custom
	Validate            []string `json:"validate,omitempty"`               // validated/granted sources
	GrantCodes          string   `json:"grant_codes,omitempty"`            // ADIF credit grant codes
	ExportCreditGranted bool     `json:"export_credit_granted,omitempty"`  // write ADIF credit_granted

	Total   int  `json:"total"`   // known denominator (0 = unknown / derive from list)
	Builtin bool `json:"builtin"` // shipped default (informational)
}

// Defaults are the built-in awards seeded on first run (then user-editable).
func Defaults() []Def {
	// Confirmed = any confirmation (LoTW or paper QSL). Validated = the stricter
	// "electronically verified" tier: LoTW only — a paper QSL confirms but does
	// NOT validate (matches ARRL/Log4OM). eQSL counts only where the program
	// accepts it (WAC).
	lq := []string{"lotw", "qsl"}
	lo := []string{"lotw"}
	return []Def{
		{Code: "DXCC", Name: "DX Century Club", Type: TypeDXCC, Field: "dxcc", Confirm: lq, Validate: lo, Total: 340, Valid: true, Builtin: true, Protected: true},
		{Code: "WAS", Name: "Worked All States", Type: TypeQSOFields, Field: "state", MatchBy: "code", ExactMatch: true, DXCCFilter: []int{291, 110, 6}, Confirm: lq, Validate: lo, Total: 50, Valid: true, Builtin: true, Protected: true},
		{Code: "WAZ", Name: "Worked All Zones (CQ)", Type: TypeQSOFields, Field: "cqz", MatchBy: "code", ExactMatch: true, Confirm: lq, Validate: lo, Total: 40, Valid: true, Builtin: true, Protected: true},
		{Code: "WAC", Name: "Worked All Continents", Type: TypeQSOFields, Field: "cont", MatchBy: "code", ExactMatch: true, Confirm: []string{"lotw", "qsl", "eqsl"}, Validate: lo, Total: 6, Valid: true, Builtin: true, Protected: true},
		{Code: "WPX", Name: "Worked All Prefixes (CQ WPX)", Type: TypeQSOFields, Field: "prefix", Dynamic: true, Confirm: lq, Validate: lo, Total: 0, Valid: true, Builtin: true, Protected: true},
		{Code: "DDFM", Name: "Départements Français Métropolitains", Type: TypeQSOFields, Field: "note", Pattern: `(?i)\b(D\d{1,2}[AB]?)\b`, DXCCFilter: []int{227}, Confirm: lq, Validate: lo, Total: 96, Valid: true, Builtin: true, Protected: true},
		{Code: "IOTA", Name: "Islands On The Air", Type: TypeReference, Field: "iota", Dynamic: true, Confirm: []string{"qsl"}, Validate: lo, Total: 0, Valid: true, Builtin: true, Protected: true},
		{Code: "POTA", Name: "Parks On The Air", Type: TypeReference, Field: "pota_ref", Dynamic: true, Confirm: lq, Validate: lo, Total: 0, Valid: true, Builtin: true, Protected: true},
		{Code: "SOTA", Name: "Summits On The Air", Type: TypeReference, Field: "sota_ref", Dynamic: true, Confirm: lq, Validate: lo, Total: 0, Valid: true, Builtin: true, Protected: true},
		{Code: "WWFF", Name: "World Wide Flora & Fauna", Type: TypeReference, Field: "wwff", Dynamic: true, Confirm: lq, Validate: lo, Total: 0, Valid: true, Builtin: true, Protected: true},
	}
}

// Migrate upgrades award definitions saved before the richer model existed.
// Such defs have Type=="" and the zero value for the new fields (notably
// Valid==false, which would otherwise hide every legacy award). For each legacy
// def it enables the award, fills the matching/confirmation fields from the
// matching built-in default (preserving the user's field/filters/confirm), and
// fixes the DDFM capture pattern. Returns the (possibly) migrated slice and
// whether anything changed. Idempotent: a def with Type!="" is left untouched.
func Migrate(defs []Def) ([]Def, bool) {
	defaults := map[string]Def{}
	for _, d := range Defaults() {
		defaults[strings.ToUpper(d.Code)] = d
	}
	const oldDDFM = `(?i)\bD(\d{1,2}[AB]?)\b`
	changed := false
	out := make([]Def, len(defs))
	for i, d := range defs {
		if d.Type != "" {
			out[i] = d // already on the new model
			continue
		}
		changed = true
		d.Valid = true // legacy defs predate the Valid flag → enable them
		if def, ok := defaults[strings.ToUpper(d.Code)]; ok {
			d.Type = def.Type
			d.ExactMatch = def.ExactMatch
			d.Dynamic = def.Dynamic
			d.Protected = def.Protected
			if len(d.Validate) == 0 {
				d.Validate = def.Validate
			}
			// Fix DDFM's capture group ("06" → "D06") so refs match the list.
			if strings.EqualFold(d.Code, "DDFM") && (d.Pattern == "" || d.Pattern == oldDDFM) {
				d.Pattern = def.Pattern
			}
		} else {
			d.Type = TypeQSOFields // sensible default for custom legacy awards
		}
		out[i] = d
	}
	return out, changed
}

// Fields lists the scannable QSO fields for the award editor.
func Fields() []string {
	return []string{
		"dxcc", "cqz", "ituz", "prefix", "callsign",
		"state", "cont", "country", "grid",
		"iota", "sota_ref", "pota_ref", "wwff",
		"name", "qth", "address", "comment", "note",
	}
}

// BandCount holds distinct-reference counts on one band.
type BandCount struct {
	Band      string `json:"band"`
	Worked    int    `json:"worked"`
	Confirmed int    `json:"confirmed"`
}

// Ref is one reference's status within an award.
type Ref struct {
	Ref            string   `json:"ref"`
	Name           string   `json:"name,omitempty"`
	Group          string   `json:"group,omitempty"`
	SubGrp         string   `json:"subgrp,omitempty"`
	Worked         bool     `json:"worked"`
	Confirmed      bool     `json:"confirmed"`
	Validated      bool     `json:"validated"`
	Bands          []string `json:"bands"`
	ConfirmedBands []string `json:"confirmed_bands"`
	ValidatedBands []string `json:"validated_bands"`
}

// Result is an award's computed progress.
type Result struct {
	Code      string      `json:"code"`
	Name      string      `json:"name"`
	Field     string      `json:"field"`
	Worked    int         `json:"worked"`
	Confirmed int         `json:"confirmed"`
	Validated int         `json:"validated"`
	Total     int         `json:"total"`
	Bands     []BandCount `json:"bands"`
	Refs      []Ref       `json:"refs"`
	Error     string      `json:"error,omitempty"` // e.g. bad regexp pattern
}

// NameResolver optionally maps a (field, ref) pair to a human name. May be nil.
type NameResolver func(field, ref string) string

type refAgg struct {
	bands          map[string]struct{}
	confirmedBands map[string]struct{}
	validatedBands map[string]struct{}
	anyConfirmed   bool
	anyValidated   bool
}

// refList is the per-award reference data Compute needs (a thin view of
// awardref.Ref, kept local so the award package stays storage-agnostic).
type refList struct {
	byCode      map[string]RefMeta // uppercased code → metadata
	codes       []string           // codes in input order (for stable unworked listing)
	withPattern []string           // codes whose reference declares a regex (usually none)
}

// RefMeta is one reference's metadata for the engine: enough to enforce a
// predefined list, per-reference DXCC scoping, a per-reference pattern, and to
// label results.
type RefMeta struct {
	Code     string
	Name     string
	Group    string
	SubGrp   string
	DXCCList []int // nil = any
	Pattern  string
	re       *regexp.Regexp
	Valid    bool
}

// NewRefList builds the engine's reference view from (code, meta) pairs.
func NewRefList(metas []RefMeta) refList {
	rl := refList{byCode: make(map[string]RefMeta, len(metas))}
	for _, m := range metas {
		code := normalizeRef(m.Code)
		if code == "" {
			continue
		}
		if p := strings.TrimSpace(m.Pattern); p != "" {
			if re, err := regexp.Compile(p); err == nil {
				m.re = re
				rl.withPattern = append(rl.withPattern, code)
			}
		}
		m.Code = code
		if _, dup := rl.byCode[code]; !dup {
			rl.codes = append(rl.codes, code)
		}
		rl.byCode[code] = m
	}
	return rl
}

// Compute runs every definition over the QSOs in a single pass. refMetas maps an
// award code to its reference metadata; awards present there with Dynamic=false
// are "predefined" (only listed references count, and the full list — including
// unworked references — appears in the result).
func Compute(defs []Def, qsos []qso.QSO, refMetas map[string][]RefMeta, nameOf NameResolver) []Result {
	refLists := make(map[string]refList, len(refMetas))
	for code, metas := range refMetas {
		refLists[strings.ToUpper(strings.TrimSpace(code))] = NewRefList(metas)
	}

	// Pre-compile award-level patterns once.
	res := make([]*regexp.Regexp, len(defs))
	perr := make([]string, len(defs))
	for i := range defs {
		if p := strings.TrimSpace(defs[i].Pattern); p != "" {
			re, err := regexp.Compile(p)
			if err != nil {
				perr[i] = "bad pattern: " + err.Error()
			} else {
				res[i] = re
			}
		}
	}

	agg := make([]map[string]*refAgg, len(defs))
	for i := range defs {
		agg[i] = map[string]*refAgg{}
	}

	for qi := range qsos {
		q := &qsos[qi]
		for i := range defs {
			d := &defs[i]
			if perr[i] != "" || !inScope(d, q) {
				continue
			}
			rl, hasList := refLists[strings.ToUpper(d.Code)]
			refs := candidates(d, res[i], q, rl, hasList)
			if len(refs) == 0 {
				continue
			}
			band := strings.ToLower(strings.TrimSpace(q.Band))
			isConf := confirmed(q, d.Confirm)
			isVal := confirmed(q, d.Validate)
			for _, ref := range refs {
				a := agg[i][ref]
				if a == nil {
					a = &refAgg{bands: map[string]struct{}{}, confirmedBands: map[string]struct{}{}, validatedBands: map[string]struct{}{}}
					agg[i][ref] = a
				}
				if band != "" {
					a.bands[band] = struct{}{}
				}
				if isConf {
					a.anyConfirmed = true
					if band != "" {
						a.confirmedBands[band] = struct{}{}
					}
				}
				if isVal {
					a.anyValidated = true
					if band != "" {
						a.validatedBands[band] = struct{}{}
					}
				}
			}
		}
	}

	out := make([]Result, len(defs))
	for i := range defs {
		d := &defs[i]
		rl, hasList := refLists[strings.ToUpper(d.Code)]
		predefined := hasList && !d.Dynamic
		r := Result{Code: d.Code, Name: d.Name, Field: d.Field, Total: d.Total, Error: perr[i]}
		bandWorked := map[string]int{}
		bandConfirmed := map[string]int{}
		for ref, a := range agg[i] {
			r.Worked++
			if a.anyConfirmed {
				r.Confirmed++
			}
			if a.anyValidated {
				r.Validated++
			}
			rf := Ref{Ref: ref, Worked: true, Confirmed: a.anyConfirmed, Validated: a.anyValidated,
				Bands: setToSorted(a.bands), ConfirmedBands: setToSorted(a.confirmedBands), ValidatedBands: setToSorted(a.validatedBands)}
			labelRef(&rf, d, ref, rl, hasList, nameOf)
			r.Refs = append(r.Refs, rf)
			for b := range a.bands {
				bandWorked[b]++
			}
			for b := range a.confirmedBands {
				bandConfirmed[b]++
			}
		}
		// Predefined awards: the full list is the denominator, and unworked
		// references are listed too (greyed in the UI).
		if predefined {
			r.Total = len(rl.codes)
			for _, code := range rl.codes {
				if _, worked := agg[i][code]; worked {
					continue
				}
				m := rl.byCode[code]
				if !m.Valid {
					continue
				}
				rf := Ref{Ref: code, Name: m.Name, Group: m.Group, SubGrp: m.SubGrp, Bands: []string{}, ConfirmedBands: []string{}, ValidatedBands: []string{}}
				if rf.Name == "" && nameOf != nil {
					rf.Name = nameOf(d.Field, code)
				}
				r.Refs = append(r.Refs, rf)
			}
		}
		sort.Slice(r.Refs, func(a, b int) bool {
			if r.Refs[a].Worked != r.Refs[b].Worked {
				return r.Refs[a].Worked // worked first
			}
			if r.Refs[a].Confirmed != r.Refs[b].Confirmed {
				return r.Refs[a].Confirmed
			}
			return natLess(r.Refs[a].Ref, r.Refs[b].Ref)
		})
		for _, b := range sortedBands(bandWorked) {
			r.Bands = append(r.Bands, BandCount{Band: b, Worked: bandWorked[b], Confirmed: bandConfirmed[b]})
		}
		out[i] = r
	}
	return out
}

// MatchQSO returns the reference codes a single QSO contributes to for one
// award (respecting scope + predefined enforcement). metas is the award's
// reference list (empty/nil for dynamic awards). Used for cell drill-down.
func MatchQSO(d Def, metas []RefMeta, q *qso.QSO) []string {
	if !inScope(&d, q) {
		return nil
	}
	var re *regexp.Regexp
	if p := strings.TrimSpace(d.Pattern); p != "" {
		if c, err := regexp.Compile(p); err == nil {
			re = c
		} else {
			return nil
		}
	}
	rl := NewRefList(metas)
	return candidates(&d, re, q, rl, len(metas) > 0)
}

// Confirmed reports whether a QSO satisfies any of the given confirmation
// sources (lotw|qsl|eqsl). Exported for the statistics view.
func Confirmed(q *qso.QSO, sources []string) bool { return confirmed(q, sources) }

// EmissionOf maps an ADIF mode to its broad category (CW|PHONE|DIGITAL).
func EmissionOf(mode string) string { return emissionOf(mode) }

// labelRef fills a worked reference's name/group from the reference list (or the
// name resolver as a fallback).
func labelRef(rf *Ref, d *Def, code string, rl refList, hasList bool, nameOf NameResolver) {
	if hasList {
		if m, ok := rl.byCode[code]; ok {
			rf.Name, rf.Group, rf.SubGrp = m.Name, m.Group, m.SubGrp
		}
	}
	if rf.Name == "" && nameOf != nil {
		rf.Name = nameOf(d.Field, code)
	}
}

// candidates extracts the reference(s) a QSO contributes to an award, enforcing
// a predefined list when one applies.
func candidates(d *Def, re *regexp.Regexp, q *qso.QSO, rl refList, hasList bool) []string {
	raw := strings.TrimSpace(stripAffix(fieldRaw(d.Field, q), d.LeadingStr, d.TrailingStr))
	if raw == "" {
		return nil
	}
	predefined := hasList && !d.Dynamic

	var found []string
	switch {
	case re != nil:
		// Award-level regex: capture group 1 (or whole match) for each hit.
		found = regexTokens(re, raw)
	case predefined && !d.ExactMatch:
		// "Search reference inside the field": look up each token of the field in
		// the list — O(tokens), not O(all references) — plus test the few
		// references that declare a regex.
		for _, tok := range tokenize(raw) {
			if _, ok := rl.byCode[tok]; ok {
				found = append(found, tok)
			}
		}
		for _, code := range rl.withPattern {
			if m := rl.byCode[code]; m.re != nil && m.re.MatchString(raw) {
				found = append(found, code)
			}
		}
	default:
		// Whole field value is the candidate.
		found = []string{normalizeRef(raw)}
	}

	if !predefined {
		return dedupe(found)
	}
	// Enforce the predefined list: keep only listed, valid references. The
	// award-level DXCCFilter already scopes which QSOs are considered (see
	// inScope), so we do NOT additionally require the QSO's entity to match the
	// reference's own DXCC — that wrongly excluded e.g. WAS Alaska (state AK is
	// DXCC entity 6, not 291). Per-reference DXCC stays metadata for the picker.
	var out []string
	seen := map[string]struct{}{}
	for _, c := range found {
		c = normalizeRef(c)
		m, ok := rl.byCode[c]
		if !ok || !m.Valid {
			continue
		}
		if _, dup := seen[c]; dup {
			continue
		}
		seen[c] = struct{}{}
		out = append(out, c)
	}
	return out
}

func regexTokens(re *regexp.Regexp, raw string) []string {
	matches := re.FindAllStringSubmatch(raw, -1)
	out := make([]string, 0, len(matches))
	for _, m := range matches {
		ref := m[0]
		if len(m) > 1 && m[1] != "" {
			ref = m[1]
		}
		if ref = normalizeRef(ref); ref != "" {
			out = append(out, ref)
		}
	}
	return dedupe(out)
}

func dedupe(in []string) []string {
	if len(in) <= 1 {
		return in
	}
	seen := make(map[string]struct{}, len(in))
	out := in[:0]
	for _, s := range in {
		if _, ok := seen[s]; ok {
			continue
		}
		seen[s] = struct{}{}
		out = append(out, s)
	}
	return out
}

// tokenize splits a field into uppercased tokens on any non-alphanumeric run,
// keeping '-' and '/' which appear inside reference codes (e.g. "FR-11553").
// The whole trimmed value is also returned so single-token fields match.
func tokenize(raw string) []string {
	up := strings.ToUpper(strings.TrimSpace(raw))
	if up == "" {
		return nil
	}
	out := []string{up}
	cur := strings.Builder{}
	for _, r := range up {
		if (r >= '0' && r <= '9') || (r >= 'A' && r <= 'Z') || r == '-' || r == '/' {
			cur.WriteRune(r)
		} else if cur.Len() > 0 {
			out = append(out, cur.String())
			cur.Reset()
		}
	}
	if cur.Len() > 0 {
		out = append(out, cur.String())
	}
	return out
}

// stripAffix removes a leading and/or trailing literal string before matching.
func stripAffix(s, lead, trail string) string {
	s = strings.TrimSpace(s)
	if lead != "" {
		s = strings.TrimPrefix(s, lead)
	}
	if trail != "" {
		s = strings.TrimSuffix(s, trail)
	}
	return s
}

func normalizeRef(s string) string { return strings.ToUpper(strings.TrimSpace(s)) }

func isDigit(b byte) bool { return b >= '0' && b <= '9' }

// natLess is a natural ("human") comparison: digit runs compare as numbers, so
// references sort 1,2,…,9,10,11 (not 1,10,11,2) and "D2A" before "D10".
func natLess(a, b string) bool {
	ia, ib := 0, 0
	for ia < len(a) && ib < len(b) {
		ca, cb := a[ia], b[ib]
		if isDigit(ca) && isDigit(cb) {
			ja, jb := ia, ib
			for ja < len(a) && isDigit(a[ja]) {
				ja++
			}
			for jb < len(b) && isDigit(b[jb]) {
				jb++
			}
			na := strings.TrimLeft(a[ia:ja], "0")
			nb := strings.TrimLeft(b[ib:jb], "0")
			if len(na) != len(nb) {
				return len(na) < len(nb) // fewer digits = smaller number
			}
			if na != nb {
				return na < nb
			}
			ia, ib = ja, jb
		} else {
			if ca != cb {
				return ca < cb
			}
			ia++
			ib++
		}
	}
	return len(a)-ia < len(b)-ib
}

// inScope reports whether a QSO falls within an award's scope (DXCC entity,
// bands, modes, emission category, validity dates).
func inScope(d *Def, q *qso.QSO) bool {
	if len(d.DXCCFilter) > 0 && !dxccAllowed(q.DXCC, d.DXCCFilter) {
		return false
	}
	if len(d.ValidBands) > 0 && !containsFold(d.ValidBands, q.Band) {
		return false
	}
	if len(d.ValidModes) > 0 && !containsFold(d.ValidModes, q.Mode) {
		return false
	}
	if len(d.Emission) > 0 && !containsFold(d.Emission, emissionOf(q.Mode)) {
		return false
	}
	if d.ValidFrom != "" && q.QSODate.Format("2006-01-02") < d.ValidFrom {
		return false
	}
	if d.ValidTo != "" && q.QSODate.Format("2006-01-02") > d.ValidTo {
		return false
	}
	return true
}

func containsFold(list []string, v string) bool {
	v = strings.TrimSpace(v)
	for _, x := range list {
		if strings.EqualFold(strings.TrimSpace(x), v) {
			return true
		}
	}
	return false
}

// emissionOf maps an ADIF mode to its broad emission category.
func emissionOf(mode string) string {
	switch strings.ToUpper(strings.TrimSpace(mode)) {
	case "CW":
		return "CW"
	case "SSB", "USB", "LSB", "AM", "FM", "DV", "DIGITALVOICE", "PHONE", "C4FM":
		return "PHONE"
	case "":
		return ""
	default:
		return "DIGITAL"
	}
}

// fieldRaw returns the raw string value of a QSO field (computed for numeric /
// derived fields). Unknown fields yield "".
func fieldRaw(field string, q *qso.QSO) string {
	switch strings.ToLower(strings.TrimSpace(field)) {
	case "dxcc":
		if q.DXCC != nil && *q.DXCC > 0 {
			return strconv.Itoa(*q.DXCC)
		}
	case "cqz":
		if q.CQZ != nil && *q.CQZ > 0 {
			return strconv.Itoa(*q.CQZ)
		}
	case "ituz":
		if q.ITUZ != nil && *q.ITUZ > 0 {
			return strconv.Itoa(*q.ITUZ)
		}
	case "prefix":
		return wpxPrefix(q.Callsign)
	case "callsign":
		return q.Callsign
	case "state":
		return q.State
	case "cont":
		return q.Continent
	case "country":
		return q.Country
	case "grid":
		return q.Grid
	case "iota":
		return q.IOTA
	case "sota_ref":
		return q.SOTARef
	case "pota_ref":
		return q.POTARef
	case "name":
		return q.Name
	case "qth":
		return q.QTH
	case "address":
		return q.Address
	case "comment":
		return q.Comment
	case "note", "notes":
		return q.Notes
	case "wwff":
		if q.Extras != nil {
			if v := strings.TrimSpace(q.Extras["WWFF_REF"]); v != "" {
				return v
			}
			if strings.EqualFold(q.Extras["SIG"], "WWFF") {
				return q.Extras["SIG_INFO"]
			}
		}
	}
	return ""
}

func dxccAllowed(dxcc *int, filter []int) bool {
	if dxcc == nil {
		return false
	}
	for _, f := range filter {
		if *dxcc == f {
			return true
		}
	}
	return false
}

// confirmed reports whether the QSO satisfies any accepted confirmation source.
// ADIF *_QSL_RCVD values Y (confirmed) and V (verified) both count.
func confirmed(q *qso.QSO, sources []string) bool {
	for _, s := range sources {
		switch s {
		case "lotw":
			if isYes(q.LOTWRcvd) {
				return true
			}
		case "qsl":
			if isYes(q.QSLRcvd) {
				return true
			}
		case "eqsl":
			if isYes(q.EQSLRcvd) {
				return true
			}
		}
	}
	return false
}

func isYes(v string) bool {
	switch strings.ToUpper(strings.TrimSpace(v)) {
	case "Y", "V":
		return true
	}
	return false
}

func setToSorted(m map[string]struct{}) []string {
	out := make([]string, 0, len(m))
	for k := range m {
		out = append(out, k)
	}
	sort.Strings(out)
	return out
}

var bandOrder = []string{"2190m", "630m", "160m", "80m", "60m", "40m", "30m", "20m", "17m", "15m", "12m", "10m", "6m", "4m", "2m", "1.25m", "70cm", "33cm", "23cm", "13cm"}

func sortedBands(m map[string]int) []string {
	idx := map[string]int{}
	for i, b := range bandOrder {
		idx[b] = i
	}
	out := make([]string, 0, len(m))
	for b := range m {
		out = append(out, b)
	}
	sort.Slice(out, func(a, b int) bool {
		ia, oka := idx[out[a]]
		ib, okb := idx[out[b]]
		if oka && okb {
			return ia < ib
		}
		if oka != okb {
			return oka
		}
		return out[a] < out[b]
	})
	return out
}