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h5t.go
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h5t.go
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package hdf5
// #include "hdf5.h"
// #include <stdlib.h>
// #include <string.h>
import "C"
import (
"fmt"
"reflect"
"runtime"
"unsafe"
)
type Datatype struct {
Location
}
type TypeClass C.H5T_class_t
const (
T_NO_CLASS TypeClass = -1 // Error
T_INTEGER TypeClass = 0 // integer types
T_FLOAT TypeClass = 1 // floating-point types
T_TIME TypeClass = 2 // date and time types
T_STRING TypeClass = 3 // character string types
T_BITFIELD TypeClass = 4 // bit field types
T_OPAQUE TypeClass = 5 // opaque types
T_COMPOUND TypeClass = 6 // compound types
T_REFERENCE TypeClass = 7 // reference types
T_ENUM TypeClass = 8 // enumeration types
T_VLEN TypeClass = 9 // variable-length types
T_ARRAY TypeClass = 10 // array types
T_NCLASSES TypeClass = 11 // nbr of classes -- MUST BE LAST
)
// list of go types
var (
_go_string_t reflect.Type = reflect.TypeOf(string(""))
_go_int_t reflect.Type = reflect.TypeOf(int(0))
_go_int8_t reflect.Type = reflect.TypeOf(int8(0))
_go_int16_t reflect.Type = reflect.TypeOf(int16(0))
_go_int32_t reflect.Type = reflect.TypeOf(int32(0))
_go_int64_t reflect.Type = reflect.TypeOf(int64(0))
_go_uint_t reflect.Type = reflect.TypeOf(uint(0))
_go_uint8_t reflect.Type = reflect.TypeOf(uint8(0))
_go_uint16_t reflect.Type = reflect.TypeOf(uint16(0))
_go_uint32_t reflect.Type = reflect.TypeOf(uint32(0))
_go_uint64_t reflect.Type = reflect.TypeOf(uint64(0))
_go_float32_t reflect.Type = reflect.TypeOf(float32(0))
_go_float64_t reflect.Type = reflect.TypeOf(float64(0))
_go_array_t reflect.Type = reflect.TypeOf([1]int{0})
_go_slice_t reflect.Type = reflect.TypeOf([]int{0})
_go_struct_t reflect.Type = reflect.TypeOf(struct{}{})
_go_ptr_t reflect.Type = reflect.PtrTo(_go_int_t)
)
type typeMap map[TypeClass]reflect.Type
var (
// Mapping of TypeClass to reflect.Type
typeClassToGoType typeMap = typeMap{
T_NO_CLASS: nil,
T_INTEGER: _go_int_t,
T_FLOAT: _go_float32_t,
T_TIME: nil,
T_STRING: _go_string_t,
T_BITFIELD: nil,
T_OPAQUE: nil,
T_COMPOUND: _go_struct_t,
T_REFERENCE: _go_ptr_t,
T_ENUM: _go_int_t,
T_VLEN: _go_slice_t,
T_ARRAY: _go_array_t,
}
parametricTypes typeMap = typeMap{
// Only these types can be used with CreateDatatype
T_COMPOUND: _go_struct_t,
T_ENUM: _go_int_t,
T_OPAQUE: nil,
T_STRING: _go_string_t,
}
)
// OpenDatatype opens a named datatype.
func OpenDatatype(c CommonFG, name string, tapl_id int) (*Datatype, error) {
c_name := C.CString(name)
defer C.free(unsafe.Pointer(c_name))
id := C.H5Topen2(C.hid_t(c.id), c_name, C.hid_t(tapl_id))
if err := checkID(id); err != nil {
return nil, err
}
return NewDatatype(id), nil
}
// NewDatatype creates a Datatype from an hdf5 id.
func NewDatatype(id C.hid_t) *Datatype {
t := &Datatype{Location{Identifier{id}}}
runtime.SetFinalizer(t, (*Datatype).finalizer)
return t
}
// CreateDatatype creates a new datatype.
// class must be T_COMPUND, T_OPAQUE, T_ENUM or T_STRING.
// size is the size of the new datatype in bytes.
func CreateDatatype(class TypeClass, size int) (*Datatype, error) {
_, ok := parametricTypes[class]
if !ok {
return nil,
fmt.Errorf(
"invalid TypeClass, want %v, %v, %v or %v, got %v",
T_COMPOUND, T_OPAQUE, T_STRING, T_ENUM,
class,
)
}
hid := C.H5Tcreate(C.H5T_class_t(class), C.size_t(size))
if err := checkID(hid); err != nil {
return nil, err
}
return NewDatatype(hid), nil
}
func (t *Datatype) finalizer() {
if err := t.Close(); err != nil {
panic(fmt.Errorf("error closing datatype: %s", err))
}
}
// GoType returns the reflect.Type associated with the Datatype's TypeClass
func (t *Datatype) GoType() reflect.Type {
return typeClassToGoType[t.Class()]
}
// Close releases a datatype.
func (t *Datatype) Close() error {
if t.id == 0 {
return nil
}
err := h5err(C.H5Tclose(t.id))
t.id = 0
return err
}
// Committed determines whether a datatype is a named type or a transient type.
func (t *Datatype) Committed() bool {
return C.H5Tcommitted(t.id) > 0
}
// Copy copies an existing datatype.
func (t *Datatype) Copy() (*Datatype, error) {
return copyDatatype(t.id)
}
// copyDatatype should be called by any function wishing to return
// an existing Datatype from a Dataset or Attribute.
func copyDatatype(id C.hid_t) (*Datatype, error) {
hid := C.H5Tcopy(id)
if err := checkID(hid); err != nil {
return nil, err
}
return NewDatatype(hid), nil
}
// Equal determines whether two datatype identifiers refer to the same datatype.
func (t *Datatype) Equal(o *Datatype) bool {
return C.H5Tequal(t.id, o.id) > 0
}
// Lock locks a datatype.
func (t *Datatype) Lock() error {
return h5err(C.H5Tlock(t.id))
}
// Size returns the size of the Datatype.
func (t *Datatype) Size() uint {
return uint(C.H5Tget_size(t.id))
}
// SetSize sets the total size of a Datatype.
func (t *Datatype) SetSize(sz uint) error {
err := C.H5Tset_size(t.id, C.size_t(sz))
return h5err(err)
}
type ArrayType struct {
Datatype
}
// NewArrayType creates a new ArrayType.
// base_type specifies the element type of the array.
// dims specify the dimensions of the array.
func NewArrayType(base_type *Datatype, dims []int) (*ArrayType, error) {
ndims := C.uint(len(dims))
c_dims := (*C.hsize_t)(unsafe.Pointer(&dims[0]))
hid := C.H5Tarray_create2(base_type.id, ndims, c_dims)
if err := checkID(hid); err != nil {
return nil, err
}
t := &ArrayType{Datatype{Location{Identifier{hid}}}}
runtime.SetFinalizer(t, (*ArrayType).finalizer)
return t, nil
}
// NDims returns the rank of an ArrayType.
func (t *ArrayType) NDims() int {
return int(C.H5Tget_array_ndims(t.id))
}
// ArrayDims returns the array dimensions.
func (t *ArrayType) ArrayDims() []int {
rank := t.NDims()
dims := make([]int, rank)
hdims := make([]C.hsize_t, rank)
slice := (*reflect.SliceHeader)(unsafe.Pointer(&hdims))
c_dims := (*C.hsize_t)(unsafe.Pointer(slice.Data))
c_rank := int(C.H5Tget_array_dims2(t.id, c_dims))
if c_rank != rank {
return nil
}
for i, n := range hdims {
dims[i] = int(n)
}
return dims
}
type VarLenType struct {
Datatype
}
// NewVarLenType creates a new VarLenType.
// base_type specifies the element type of the VarLenType.
func NewVarLenType(base_type *Datatype) (*VarLenType, error) {
id := C.H5Tvlen_create(base_type.id)
if err := checkID(id); err != nil {
return nil, err
}
t := &VarLenType{Datatype{Location{Identifier{id}}}}
runtime.SetFinalizer(t, (*VarLenType).finalizer)
return t, nil
}
// IsVariableStr determines whether the VarLenType is a string.
func (vl *VarLenType) IsVariableStr() bool {
return C.H5Tis_variable_str(vl.id) > 0
}
type CompoundType struct {
Datatype
}
// NewCompoundType creates a new CompoundType.
// size is the size in bytes of the compound datatype.
func NewCompoundType(size int) (*CompoundType, error) {
id := C.H5Tcreate(C.H5T_class_t(T_COMPOUND), C.size_t(size))
if err := checkID(id); err != nil {
return nil, err
}
t := &CompoundType{Datatype{Location{Identifier{id}}}}
runtime.SetFinalizer(t, (*CompoundType).finalizer)
return t, nil
}
// NMembers returns the number of elements in a compound or enumeration datatype.
func (t *CompoundType) NMembers() int {
return int(C.H5Tget_nmembers(t.id))
}
// Class returns the TypeClass of the DataType
func (t *Datatype) Class() TypeClass {
return TypeClass(C.H5Tget_class(t.id))
}
// MemberClass returns datatype class of compound datatype member.
func (t *CompoundType) MemberClass(mbr_idx int) TypeClass {
return TypeClass(C.H5Tget_member_class(t.id, C.uint(mbr_idx)))
}
// MemberName returns the name of a compound or enumeration datatype member.
func (t *CompoundType) MemberName(mbr_idx int) string {
c_name := C.H5Tget_member_name(t.id, C.uint(mbr_idx))
defer C.free(unsafe.Pointer(c_name))
return C.GoString(c_name)
}
// MemberIndex returns the index of a compound or enumeration datatype member.
func (t *CompoundType) MemberIndex(name string) int {
c_name := C.CString(name)
defer C.free(unsafe.Pointer(c_name))
return int(C.H5Tget_member_index(t.id, c_name))
}
// MemberOffset returns the offset of a field of a compound datatype.
func (t *CompoundType) MemberOffset(mbr_idx int) int {
return int(C.H5Tget_member_offset(t.id, C.uint(mbr_idx)))
}
// MemberType returns the datatype of the specified member.
func (t *CompoundType) MemberType(mbr_idx int) (*Datatype, error) {
hid := C.H5Tget_member_type(t.id, C.uint(mbr_idx))
if err := checkID(hid); err != nil {
return nil, err
}
return NewDatatype(hid), nil
}
// Insert adds a new member to a compound datatype.
func (t *CompoundType) Insert(name string, offset int, field *Datatype) error {
cname := C.CString(name)
defer C.free(unsafe.Pointer(cname))
return h5err(C.H5Tinsert(t.id, cname, C.size_t(offset), field.id))
}
// Pack recursively removes padding from within a compound datatype.
// This is analogous to C struct packing and will give a space-efficient
// type on the disk. However, using this may require type conversions
// on more machines, so may be a worse option.
func (t *CompoundType) Pack() error {
return h5err(C.H5Tpack(t.id))
}
type OpaqueDatatype struct {
Datatype
}
// SetTag tags an opaque datatype.
func (t *OpaqueDatatype) SetTag(tag string) error {
ctag := C.CString(tag)
defer C.free(unsafe.Pointer(ctag))
return h5err(C.H5Tset_tag(t.id, ctag))
}
// Tag returns the tag associated with an opaque datatype.
func (t *OpaqueDatatype) Tag() string {
cname := C.H5Tget_tag(t.id)
if cname != nil {
defer C.free(unsafe.Pointer(cname))
return C.GoString(cname)
}
return ""
}
// NewDatatypeFromValue creates a datatype from a value in an interface.
func NewDatatypeFromValue(v interface{}) (*Datatype, error) {
return NewDataTypeFromType(reflect.TypeOf(v))
}
// NewDatatypeFromType creates a new Datatype from a reflect.Type.
func NewDataTypeFromType(t reflect.Type) (*Datatype, error) {
var dt *Datatype = nil
var err error
switch t.Kind() {
case reflect.Int:
dt, err = T_NATIVE_INT.Copy()
case reflect.Int8:
dt, err = T_NATIVE_INT8.Copy()
case reflect.Int16:
dt, err = T_NATIVE_INT16.Copy()
case reflect.Int32:
dt, err = T_NATIVE_INT32.Copy()
case reflect.Int64:
dt, err = T_NATIVE_INT64.Copy()
case reflect.Uint:
dt, err = T_NATIVE_UINT.Copy()
case reflect.Uint8:
dt, err = T_NATIVE_UINT8.Copy()
case reflect.Uint16:
dt, err = T_NATIVE_UINT16.Copy()
case reflect.Uint32:
dt, err = T_NATIVE_UINT32.Copy()
case reflect.Uint64:
dt, err = T_NATIVE_UINT64.Copy()
case reflect.Float32:
dt, err = T_NATIVE_FLOAT.Copy()
case reflect.Float64:
dt, err = T_NATIVE_DOUBLE.Copy()
case reflect.String:
dt, err = T_GO_STRING.Copy()
case reflect.Array:
elem_type, err := NewDataTypeFromType(t.Elem())
if err != nil {
return nil, err
}
dims := getArrayDims(t)
adt, err := NewArrayType(elem_type, dims)
if err != nil {
return nil, err
}
dt = &adt.Datatype
case reflect.Slice:
elem_type, err := NewDataTypeFromType(t.Elem())
if err != nil {
return nil, err
}
sdt, err := NewVarLenType(elem_type)
if err != nil {
return nil, err
}
dt = &sdt.Datatype
case reflect.Struct:
sz := int(t.Size())
cdt, err := NewCompoundType(sz)
if err != nil {
return nil, err
}
n := t.NumField()
for i := 0; i < n; i++ {
f := t.Field(i)
var field_dt *Datatype = nil
field_dt, err = NewDataTypeFromType(f.Type)
if err != nil {
return nil, err
}
offset := int(f.Offset + 0)
if field_dt == nil {
return nil, fmt.Errorf("pb with field [%d-%s]", i, f.Name)
}
field_name := string(f.Tag)
if len(field_name) == 0 {
field_name = f.Name
}
err = cdt.Insert(field_name, offset, field_dt)
if err != nil {
return nil, fmt.Errorf("pb with field [%d-%s]: %s", i, f.Name, err)
}
}
dt = &cdt.Datatype
default:
// Should never happen.
panic(fmt.Errorf("unhandled kind (%v)", t.Kind()))
}
return dt, err
}
func getArrayDims(dt reflect.Type) []int {
result := []int{}
if dt.Kind() == reflect.Array {
result = append(result, dt.Len())
for _, dim := range getArrayDims(dt.Elem()) {
result = append(result, dim)
}
}
return result
}