package ent import ( "math" "github.com/jordanorelli/hyperstone/bit" "github.com/jordanorelli/hyperstone/dota" ) const ( f_min = 1 << iota f_max f_center ) func floatType(flat *dota.ProtoFlattenedSerializerFieldT, env *Env) tÿpe { if env.symbol(int(flat.GetVarTypeSym())) == "CNetworkedQuantizedFloat" { return qFloatType(flat, env) } if env.symbol(int(flat.GetVarEncoderSym())) == "coord" { return nil } if env.symbol(int(flat.GetFieldSerializerNameSym())) == "simulationtime" { return nil } switch flat.GetBitCount() { case 0, 32: return typeFn(float_t) default: return nil } } func qFloatType(flat *dota.ProtoFlattenedSerializerFieldT, env *Env) tÿpe { if flat.GetBitCount() < 0 { return typeError("quantized float has invalid negative bit count specifier") } if flat.GetHighValue()-flat.GetLowValue() < 0 { return typeError("quantized float has invalid negative range") } t := qfloat_t{ bits: uint(flat.GetBitCount()), low: flat.GetLowValue(), high: flat.GetHighValue(), flags: int(flat.GetEncodeFlags()) & 0x7, } t.span = t.high - t.low t.intervals = uint(1< 0 { t.special = new(float32) switch t.flags { case f_min: *t.special = t.low case f_max: *t.special = t.high case f_center: *t.special = t.low + (t.high+t.low)*0.5 default: return typeError("dunno how to handle qfloat flag value: %d", t.flags) } } return t } type qfloat_t struct { bits uint low float32 high float32 flags int span float32 // total range of values intervals uint // number of intervals in the quantization range interval float32 // width of one interval special *float32 } func (t qfloat_t) read(r bit.Reader) (value, error) { if t.special != nil && bit.ReadBool(r) { return *t.special, nil } return t.low + float32(r.ReadBits(t.bits))*t.interval, r.Err() } func float_t(r bit.Reader) (value, error) { // TODO: check uint32 overflow here? return math.Float32frombits(uint32(r.ReadBits(32))), r.Err() }