void
HLWriter_Add_Inverted_Doc_IMP(HighlightWriter *self, Inverter *inverter,
int32_t doc_id) {
HighlightWriterIVARS *const ivars = HLWriter_IVARS(self);
OutStream *dat_out = S_lazy_init(self);
OutStream *ix_out = ivars->ix_out;
int64_t filepos = OutStream_Tell(dat_out);
uint32_t num_highlightable = 0;
int32_t expected = (int32_t)(OutStream_Tell(ix_out) / 8);
// Verify doc id.
if (doc_id != expected) {
THROW(ERR, "Expected doc id %i32 but got %i32", expected, doc_id);
}
// Write index data.
OutStream_Write_I64(ix_out, filepos);
// Count, then write number of highlightable fields.
Inverter_Iterate(inverter);
while (Inverter_Next(inverter)) {
FieldType *type = Inverter_Get_Type(inverter);
if (FType_Is_A(type, FULLTEXTTYPE)
&& FullTextType_Highlightable((FullTextType*)type)
) {
num_highlightable++;
}
}
OutStream_Write_C32(dat_out, num_highlightable);
Inverter_Iterate(inverter);
while (Inverter_Next(inverter)) {
FieldType *type = Inverter_Get_Type(inverter);
if (FType_Is_A(type, FULLTEXTTYPE)
&& FullTextType_Highlightable((FullTextType*)type)
) {
String *field = Inverter_Get_Field_Name(inverter);
Inversion *inversion = Inverter_Get_Inversion(inverter);
ByteBuf *tv_buf = HLWriter_TV_Buf(self, inversion);
Freezer_serialize_string(field, dat_out);
Freezer_serialize_bytebuf(tv_buf, dat_out);
DECREF(tv_buf);
}
}
}
void
HLWriter_add_inverted_doc(HighlightWriter *self, Inverter *inverter,
i32_t doc_id)
{
OutStream *dat_out = S_lazy_init(self);
OutStream *ix_out = self->ix_out;
i64_t filepos = OutStream_Tell(dat_out);
u32_t num_highlightable = 0;
i32_t expected = (i32_t)(OutStream_Tell(ix_out) / 8);
/* Verify doc id. */
if (doc_id != expected)
THROW("Expected doc id %i32 but got %i32", expected, doc_id);
/* Write index data. */
OutStream_Write_U64(ix_out, filepos);
/* Count, then write number of highlightable fields. */
Inverter_Iter_Init(inverter);
while (Inverter_Next(inverter)) {
FieldType *type = Inverter_Get_Type(inverter);
if ( OBJ_IS_A(type, FULLTEXTTYPE)
&& FullTextType_Highlightable(type)
) {
num_highlightable++;
}
}
OutStream_Write_C32(dat_out, num_highlightable);
Inverter_Iter_Init(inverter);
while (Inverter_Next(inverter)) {
FieldType *type = Inverter_Get_Type(inverter);
if ( OBJ_IS_A(type, FULLTEXTTYPE)
&& FullTextType_Highlightable(type)
) {
CharBuf *field = Inverter_Get_Field_Name(inverter);
Inversion *inversion = Inverter_Get_Inversion(inverter);
ByteBuf *tv_buf = HLWriter_TV_Buf(self, inversion);
CB_Serialize(field, dat_out);
BB_Serialize(tv_buf, dat_out);
DECREF(tv_buf);
}
}
}
void
DocWriter_add_inverted_doc(DocWriter *self, Inverter *inverter,
int32_t doc_id) {
OutStream *dat_out = S_lazy_init(self);
OutStream *ix_out = self->ix_out;
uint32_t num_stored = 0;
int64_t start = OutStream_Tell(dat_out);
int64_t expected = OutStream_Tell(ix_out) / 8;
// Verify doc id.
if (doc_id != expected) {
THROW(ERR, "Expected doc id %i64 but got %i32", expected, doc_id);
}
// Write the number of stored fields.
Inverter_Iterate(inverter);
while (Inverter_Next(inverter)) {
FieldType *type = Inverter_Get_Type(inverter);
if (FType_Stored(type)) { num_stored++; }
}
OutStream_Write_C32(dat_out, num_stored);
Inverter_Iterate(inverter);
while (Inverter_Next(inverter)) {
// Only store fields marked as "stored".
FieldType *type = Inverter_Get_Type(inverter);
if (FType_Stored(type)) {
CharBuf *field = Inverter_Get_Field_Name(inverter);
Obj *value = Inverter_Get_Value(inverter);
CB_Serialize(field, dat_out);
Obj_Serialize(value, dat_out);
}
}
// Write file pointer.
OutStream_Write_I64(ix_out, start);
}
void
DocWriter_Add_Inverted_Doc_IMP(DocWriter *self, Inverter *inverter,
int32_t doc_id) {
DocWriterIVARS *const ivars = DocWriter_IVARS(self);
OutStream *dat_out = S_lazy_init(self);
OutStream *ix_out = ivars->ix_out;
uint32_t num_stored = 0;
int64_t start = OutStream_Tell(dat_out);
int64_t expected = OutStream_Tell(ix_out) / 8;
// Verify doc id.
if (doc_id != expected) {
THROW(ERR, "Expected doc id %i64 but got %i32", expected, doc_id);
}
// Write the number of stored fields.
Inverter_Iterate(inverter);
while (Inverter_Next(inverter)) {
FieldType *type = Inverter_Get_Type(inverter);
if (FType_Stored(type)) { num_stored++; }
}
OutStream_Write_C32(dat_out, num_stored);
Inverter_Iterate(inverter);
while (Inverter_Next(inverter)) {
// Only store fields marked as "stored".
FieldType *type = Inverter_Get_Type(inverter);
if (FType_Stored(type)) {
String *field = Inverter_Get_Field_Name(inverter);
Obj *value = Inverter_Get_Value(inverter);
Freezer_serialize_string(field, dat_out);
switch (FType_Primitive_ID(type) & FType_PRIMITIVE_ID_MASK) {
case FType_TEXT: {
const char *buf = Str_Get_Ptr8((String*)value);
size_t size = Str_Get_Size((String*)value);
OutStream_Write_C32(dat_out, size);
OutStream_Write_Bytes(dat_out, buf, size);
break;
}
case FType_BLOB: {
char *buf = BB_Get_Buf((ByteBuf*)value);
size_t size = BB_Get_Size((ByteBuf*)value);
OutStream_Write_C32(dat_out, size);
OutStream_Write_Bytes(dat_out, buf, size);
break;
}
case FType_INT32: {
int32_t val = Int32_Get_Value((Integer32*)value);
OutStream_Write_C32(dat_out, val);
break;
}
case FType_INT64: {
int64_t val = Int64_Get_Value((Integer64*)value);
OutStream_Write_C64(dat_out, val);
break;
}
case FType_FLOAT32: {
float val = Float32_Get_Value((Float32*)value);
OutStream_Write_F32(dat_out, val);
break;
}
case FType_FLOAT64: {
double val = Float64_Get_Value((Float64*)value);
OutStream_Write_F64(dat_out, val);
break;
}
default:
THROW(ERR, "Unrecognized type: %o", type);
}
}
}
// Write file pointer.
OutStream_Write_I64(ix_out, start);
}
