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query.sql.go
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// Code generated by pggen. DO NOT EDIT.
package nested
import (
"context"
"fmt"
"github.com/jackc/pgconn"
"github.com/jackc/pgtype"
"github.com/jackc/pgx/v4"
)
// Querier is a typesafe Go interface backed by SQL queries.
type Querier interface {
ArrayNested2(ctx context.Context) ([]ProductImageType, error)
Nested3(ctx context.Context) ([]ProductImageSetType, error)
}
var _ Querier = &DBQuerier{}
type DBQuerier struct {
conn genericConn // underlying Postgres transport to use
types *typeResolver // resolve types by name
}
// genericConn is a connection like *pgx.Conn, pgx.Tx, or *pgxpool.Pool.
type genericConn interface {
Query(ctx context.Context, sql string, args ...any) (pgx.Rows, error)
QueryRow(ctx context.Context, sql string, args ...any) pgx.Row
Exec(ctx context.Context, sql string, arguments ...any) (pgconn.CommandTag, error)
}
// NewQuerier creates a DBQuerier that implements Querier.
func NewQuerier(conn genericConn) *DBQuerier {
return &DBQuerier{conn: conn, types: newTypeResolver()}
}
// Dimensions represents the Postgres composite type "dimensions".
type Dimensions struct {
Width int `json:"width"`
Height int `json:"height"`
}
// ProductImageSetType represents the Postgres composite type "product_image_set_type".
type ProductImageSetType struct {
Name string `json:"name"`
OrigImage ProductImageType `json:"orig_image"`
Images []ProductImageType `json:"images"`
}
// ProductImageType represents the Postgres composite type "product_image_type".
type ProductImageType struct {
Source string `json:"source"`
Dimensions Dimensions `json:"dimensions"`
}
// typeResolver looks up the pgtype.ValueTranscoder by Postgres type name.
type typeResolver struct {
connInfo *pgtype.ConnInfo // types by Postgres type name
}
func newTypeResolver() *typeResolver {
ci := pgtype.NewConnInfo()
return &typeResolver{connInfo: ci}
}
// findValue find the OID, and pgtype.ValueTranscoder for a Postgres type name.
func (tr *typeResolver) findValue(name string) (uint32, pgtype.ValueTranscoder, bool) {
typ, ok := tr.connInfo.DataTypeForName(name)
if !ok {
return 0, nil, false
}
v := pgtype.NewValue(typ.Value)
return typ.OID, v.(pgtype.ValueTranscoder), true
}
// setValue sets the value of a ValueTranscoder to a value that should always
// work and panics if it fails.
func (tr *typeResolver) setValue(vt pgtype.ValueTranscoder, val interface{}) pgtype.ValueTranscoder {
if err := vt.Set(val); err != nil {
panic(fmt.Sprintf("set ValueTranscoder %T to %+v: %s", vt, val, err))
}
return vt
}
type compositeField struct {
name string // name of the field
typeName string // Postgres type name
defaultVal pgtype.ValueTranscoder // default value to use
}
func (tr *typeResolver) newCompositeValue(name string, fields ...compositeField) pgtype.ValueTranscoder {
if _, val, ok := tr.findValue(name); ok {
return val
}
fs := make([]pgtype.CompositeTypeField, len(fields))
vals := make([]pgtype.ValueTranscoder, len(fields))
isBinaryOk := true
for i, field := range fields {
oid, val, ok := tr.findValue(field.typeName)
if !ok {
oid = unknownOID
val = field.defaultVal
}
isBinaryOk = isBinaryOk && oid != unknownOID
fs[i] = pgtype.CompositeTypeField{Name: field.name, OID: oid}
vals[i] = val
}
// Okay to ignore error because it's only thrown when the number of field
// names does not equal the number of ValueTranscoders.
typ, _ := pgtype.NewCompositeTypeValues(name, fs, vals)
if !isBinaryOk {
return textPreferrer{ValueTranscoder: typ, typeName: name}
}
return typ
}
func (tr *typeResolver) newArrayValue(name, elemName string, defaultVal func() pgtype.ValueTranscoder) pgtype.ValueTranscoder {
if _, val, ok := tr.findValue(name); ok {
return val
}
elemOID, elemVal, ok := tr.findValue(elemName)
elemValFunc := func() pgtype.ValueTranscoder {
return pgtype.NewValue(elemVal).(pgtype.ValueTranscoder)
}
if !ok {
elemOID = unknownOID
elemValFunc = defaultVal
}
typ := pgtype.NewArrayType(name, elemOID, elemValFunc)
if elemOID == unknownOID {
return textPreferrer{ValueTranscoder: typ, typeName: name}
}
return typ
}
// newDimensions creates a new pgtype.ValueTranscoder for the Postgres
// composite type 'dimensions'.
func (tr *typeResolver) newDimensions() pgtype.ValueTranscoder {
return tr.newCompositeValue(
"dimensions",
compositeField{name: "width", typeName: "int4", defaultVal: &pgtype.Int4{}},
compositeField{name: "height", typeName: "int4", defaultVal: &pgtype.Int4{}},
)
}
// newProductImageSetType creates a new pgtype.ValueTranscoder for the Postgres
// composite type 'product_image_set_type'.
func (tr *typeResolver) newProductImageSetType() pgtype.ValueTranscoder {
return tr.newCompositeValue(
"product_image_set_type",
compositeField{name: "name", typeName: "text", defaultVal: &pgtype.Text{}},
compositeField{name: "orig_image", typeName: "product_image_type", defaultVal: tr.newProductImageType()},
compositeField{name: "images", typeName: "_product_image_type", defaultVal: tr.newProductImageTypeArray()},
)
}
// newProductImageType creates a new pgtype.ValueTranscoder for the Postgres
// composite type 'product_image_type'.
func (tr *typeResolver) newProductImageType() pgtype.ValueTranscoder {
return tr.newCompositeValue(
"product_image_type",
compositeField{name: "source", typeName: "text", defaultVal: &pgtype.Text{}},
compositeField{name: "dimensions", typeName: "dimensions", defaultVal: tr.newDimensions()},
)
}
// newProductImageTypeArray creates a new pgtype.ValueTranscoder for the Postgres
// '_product_image_type' array type.
func (tr *typeResolver) newProductImageTypeArray() pgtype.ValueTranscoder {
return tr.newArrayValue("_product_image_type", "product_image_type", tr.newProductImageType)
}
const arrayNested2SQL = `SELECT
ARRAY [
ROW ('img2', ROW (22, 22)::dimensions)::product_image_type,
ROW ('img3', ROW (33, 33)::dimensions)::product_image_type
] AS images;`
// ArrayNested2 implements Querier.ArrayNested2.
func (q *DBQuerier) ArrayNested2(ctx context.Context) ([]ProductImageType, error) {
ctx = context.WithValue(ctx, "pggen_query_name", "ArrayNested2")
row := q.conn.QueryRow(ctx, arrayNested2SQL)
item := []ProductImageType{}
imagesArray := q.types.newProductImageTypeArray()
if err := row.Scan(imagesArray); err != nil {
return item, fmt.Errorf("query ArrayNested2: %w", err)
}
if err := imagesArray.AssignTo(&item); err != nil {
return item, fmt.Errorf("assign ArrayNested2 row: %w", err)
}
return item, nil
}
const nested3SQL = `SELECT
ROW (
'name', -- name
ROW ('img1', ROW (11, 11)::dimensions)::product_image_type, -- orig_image
ARRAY [ --images
ROW ('img2', ROW (22, 22)::dimensions)::product_image_type,
ROW ('img3', ROW (33, 33)::dimensions)::product_image_type
]
)::product_image_set_type;`
// Nested3 implements Querier.Nested3.
func (q *DBQuerier) Nested3(ctx context.Context) ([]ProductImageSetType, error) {
ctx = context.WithValue(ctx, "pggen_query_name", "Nested3")
rows, err := q.conn.Query(ctx, nested3SQL)
if err != nil {
return nil, fmt.Errorf("query Nested3: %w", err)
}
defer rows.Close()
items := []ProductImageSetType{}
rowRow := q.types.newProductImageSetType()
for rows.Next() {
var item ProductImageSetType
if err := rows.Scan(rowRow); err != nil {
return nil, fmt.Errorf("scan Nested3 row: %w", err)
}
if err := rowRow.AssignTo(&item); err != nil {
return nil, fmt.Errorf("assign Nested3 row: %w", err)
}
items = append(items, item)
}
if err := rows.Err(); err != nil {
return nil, fmt.Errorf("close Nested3 rows: %w", err)
}
return items, err
}
// textPreferrer wraps a pgtype.ValueTranscoder and sets the preferred encoding
// format to text instead binary (the default). pggen uses the text format
// when the OID is unknownOID because the binary format requires the OID.
// Typically occurs for unregistered types.
type textPreferrer struct {
pgtype.ValueTranscoder
typeName string
}
// PreferredParamFormat implements pgtype.ParamFormatPreferrer.
func (t textPreferrer) PreferredParamFormat() int16 { return pgtype.TextFormatCode }
func (t textPreferrer) NewTypeValue() pgtype.Value {
return textPreferrer{ValueTranscoder: pgtype.NewValue(t.ValueTranscoder).(pgtype.ValueTranscoder), typeName: t.typeName}
}
func (t textPreferrer) TypeName() string {
return t.typeName
}
// unknownOID means we don't know the OID for a type. This is okay for decoding
// because pgx call DecodeText or DecodeBinary without requiring the OID. For
// encoding parameters, pggen uses textPreferrer if the OID is unknown.
const unknownOID = 0