Add support for DS248x i2c to onewire interface chip, and DS18B20 temp sensors (#59)

10 years ago · 3bb6afb0ac
parent 495d261bae
commit 3bb6afb0ac
5 changed files with 776 additions and 0 deletions
--- a/experimental/devices/ds18b20/ds18b20.go
+++ b/experimental/devices/ds18b20/ds18b20.go
@ -0,0 +1,165 @@
 // Copyright 2016 The Periph Authors. All rights reserved.
 // Use of this source code is governed under the Apache License, Version 2.0
 // that can be found in the LICENSE file.
 // Package ds18b20 interfaces to Dallas Semi / Maxim DS18B20 and MAX31820
 // 1-wire temperature sensors.
 //
 // Note that both DS18B20 and MAX31820 use family code 0x28.
 //
 // Both powered sensors and parasitically powered sensors are supported
 // as long as the bus driver can provide sufficient power using an active
 // pull-up.
 //
 // The DS18B20 alarm functionality and reading/writing the 2 alarm bytes in
 // the EEPROM are not supported. The DS18S20 is also not supported.
 //
 // Datasheets
 //
 // https://datasheets.maximintegrated.com/en/ds/DS18B20-PAR.pdf
 //
 // http://datasheets.maximintegrated.com/en/ds/MAX31820.pdf
 package ds18b20
 import (
 	"errors"
 	"time"
 	"github.com/google/periph/devices"
 	"github.com/google/periph/experimental/conn/onewire"
 )
 // New returns an object that communicates over 1-wire to the DS18B20 sensor with the
 // specified 64-bit address.
 //
 // resolutionBits must be in the range 9..12 and determines how many bits of precision
 // the readings have. The resolution affects the conversion time: 9bits:94ms, 10bits:188ms,
 // 11bits:375ms, 12bits:750ms.
 //
 // A resolution of 10 bits corresponds to 0.25C and tends to be a good compromise between
 // conversion time and the device's inherent accuracy of +/-0.5C.
 func New(o onewire.Bus, addr onewire.Address, resolutionBits int) (*Dev, error) {
 	if resolutionBits < 9 || resolutionBits > 12 {
 		return nil, errors.New("ds18b20: invalid resolutionBits")
 	}
 	d := &Dev{onewire: onewire.Dev{Bus: o, Addr: addr}, resolution: resolutionBits}
 	// Start by reading the scratchpad memory, this will tell us whether we can talk to the
 	// device correctly and also how it's configured.
 	spad, err := d.readScratchpad()
 	if err != nil {
 		return nil, err
 	}
 	// Change the resolution, if necessary (datasheet p.6).
 	if int(spad[4]>>5) != resolutionBits-9 {
 		// Set the value in the configuration register.
 		d.onewire.Tx([]byte{0x4e, 0, 0, byte((resolutionBits-9)<<5) | 0x1f}, nil)
 		// Copy the scratchpad to EEPROM to save the values.
 		d.onewire.TxPower([]byte{0x48}, nil)
 		// Wait for the write to complete
 		time.Sleep(10 * time.Millisecond)
 	}
 	return d, nil
 }
 // ConvertAll performs a conversion on all DS18B20 devices on the bus.
 //
 // During the conversion it places the bus in strong pull-up mode to
 // power parasitic devices and returns when the conversions have
 // completed. This time period is determined by the maximum
 // resolution of all devices on the bus and must be provided.
 //
 // ConvertAll uses time.Sleep to wait for the conversion to finish,
 // which takes from 94ms to 752ms.
 func ConvertAll(o onewire.Bus, maxResolutionBits int) error {
 	if maxResolutionBits < 9 || maxResolutionBits > 12 {
 		return errors.New("ds18b20: invalid maxResolutionBits")
 	}
 	if err := o.Tx([]byte{0xcc, 0x44}, nil, onewire.StrongPullup); err != nil {
 		return err
 	}
 	conversionSleep(maxResolutionBits)
 	return nil
 }
 //===== Dev
 // Dev is a handle to a Dallas Semi / Maxim DS18B20 temperature sensor on a 1-wire bus.
 type Dev struct {
 	onewire    onewire.Dev // device on 1-wire bus
 	resolution int         // resolution in bits (9..12)
 }
 // Temperature performs a conversion and returns the temperature.
 func (d *Dev) Temperature() (devices.Celsius, error) {
 	if err := d.onewire.TxPower([]byte{0x44}, nil); err != nil {
 		return 0, err
 	}
 	conversionSleep(d.resolution)
 	return d.LastTemp()
 }
 // LastTemp reads the temperature resulting from the last conversion from the device.
 // It is useful in combination with ConvertAll.
 func (d *Dev) LastTemp() (devices.Celsius, error) {
 	// Read the scratchpad memory.
 	spad, err := d.readScratchpad()
 	if err != nil {
 		return 0, err
 	}
 	// spad[1] is MSB, spad[0] is LSB and has 4 fractional bits. Need to do sign extension
 	// multiply by 1000 to get devices.Millis, divide by 16 due to 4 fractional bits.
 	// Datasheet p.4.
 	c := (devices.Celsius(int8(spad[1]))<<8 + devices.Celsius(spad[0])) * 1000 / 16
 	// The device powers up with a value of 85°C, so if we read that odds are very high
 	// that either no conversion was performed or that the conversion failed due to lack of
 	// power. This prevents reading a temp of exactly 85°C, but that seems like the right
 	// tradeoff.
 	if c == 85000 {
 		return 0, busError("ds18b20: has not performed a temperature conversion (insufficient pull-up?)")
 	}
 	return c, nil
 }
 //
 // busError implements error and onewire.BusError.
 type busError string
 func (e busError) Error() string  { return string(e) }
 func (e busError) BusError() bool { return true }
 // conversionSleep sleeps for the time a conversion takes, which depends
 // on the resolution:
 // 9bits:94ms, 10bits:188ms, 11bits:376ms, 12bits:752ms, datasheet p.6.
 func conversionSleep(bits int) {
 	time.Sleep((94 << uint(bits-9)) * time.Millisecond)
 }
 // readScratchpad reads the 9 bytes of scratchpad and checks the CRC.
 // It returns the 8 bytes of scratchpad data (excluding the CRC byte).
 func (d *Dev) readScratchpad() ([]byte, error) {
 	// Read the scratchpad memory.
 	var spad [9]byte
 	if err := d.onewire.Tx([]byte{0xbe}, spad[:]); err != nil {
 		return nil, err
 	}
 	// Check the scratchpad CRC.
 	if !onewire.CheckCRC(spad[:]) {
 		for _, s := range spad {
 			if s != 0xff {
 				return nil, busError("ds18b20: incorrect scratchpad CRC")
 			}
 		}
 		return nil, busError("ds18b20: device did not respond")
 	}
 	return spad[:8], nil
 }
--- a/experimental/devices/ds18b20/ds18b20_test.go
+++ b/experimental/devices/ds18b20/ds18b20_test.go
@ -0,0 +1,153 @@
 // Copyright 2016 The Periph Authors. All rights reserved.
 // Use of this source code is governed under the Apache License, Version 2.0
 // that can be found in the LICENSE file.
 package ds18b20
 import (
 	"os"
 	"testing"
 	"time"
 	"github.com/google/periph/devices"
 	"github.com/google/periph/experimental/conn/onewire"
 	"github.com/google/periph/experimental/conn/onewire/onewiretest"
 	"github.com/google/periph/host"
 )
 // TestMain lets periph load all drivers and then runs the tests.
 func TestMain(m *testing.M) {
 	host.Init()
 	os.Exit(m.Run())
 }
 // TestTemperature tests a temperature conversion on a ds18b20 using
 // recorded bus transactions.
 func TestTemperature(t *testing.T) {
 	// set-up playback using the recording output.
 	ops := []onewiretest.IO{
 		// Match ROM + Read Scratchpad (init)
 		{Write: []uint8{0x55, 0x28, 0xac, 0x41, 0xe, 0x7, 0x0, 0x0, 0x74, 0xbe},
 			Read: []uint8{0xe0, 0x1, 0x0, 0x0, 0x3f, 0xff, 0x10, 0x10, 0x3f}, Pull: false},
 		// Match ROM + Convert
 		{Write: []uint8{0x55, 0x28, 0xac, 0x41, 0xe, 0x7, 0x0, 0x0, 0x74, 0x44},
 			Read: []uint8(nil), Pull: true},
 		// Match ROM + Read Scratchpad (read temp)
 		{Write: []uint8{0x55, 0x28, 0xac, 0x41, 0xe, 0x7, 0x0, 0x0, 0x74, 0xbe},
 			Read: []uint8{0xe0, 0x1, 0x0, 0x0, 0x3f, 0xff, 0x10, 0x10, 0x3f}, Pull: false},
 	}
 	var addr onewire.Address = 0x740000070e41ac28
 	var temp devices.Celsius = 30000 // 30.000°C
 	owBus := &onewiretest.Playback{Ops: ops}
 	// Init the ds18b20.
 	ds18b20, err := New(owBus, addr, 10)
 	if err != nil {
 		t.Fatal(err)
 	}
 	// Read the temperature.
 	t0 := time.Now()
 	now, err := ds18b20.Temperature()
 	dt := time.Since(t0)
 	if err != nil {
 		t.Fatal(err)
 	}
 	// Expect the correct value.
 	if now != temp {
 		t.Errorf("expected %s, got %s", temp.String(), now.String())
 	}
 	// Expect it to take >187ms
 	if dt < 188*time.Millisecond {
 		t.Errorf("expected conversion to take >187ms, took %s", dt)
 	}
 }
 // TestConvertAll tests a temperature conversion on all ds18b20 using
 // recorded bus transactions.
 func TestConvertAll(t *testing.T) {
 	// set-up playback using the recording output.
 	ops := []onewiretest.IO{
 		// Skip ROM + Convert
 		{Write: []uint8{0xcc, 0x44}, Read: []uint8(nil), Pull: true},
 	}
 	owBus := &onewiretest.Playback{Ops: ops}
 	// Perform the conversion
 	t0 := time.Now()
 	if err := ConvertAll(owBus, 9); err != nil {
 		t.Fatal(err)
 	}
 	// Expect it to take >93ms
 	if dt := time.Since(t0); dt < 94*time.Millisecond {
 		t.Errorf("expected conversion to take >93ms, took %s", dt)
 	}
 }
 /* Commented out in order not to import periph/host, need to move to smoke test
 // TestRecordTemp tests and records a temperature conversion. It outputs
 // the recording if the tests are run with the verbose option.
 //
 // This test is skipped unless the -record flag is passed to the test executable.
 // Use either `go test -args -record` or `ds18b20.test -test.v -record`.
 func TestRecordTemp(t *testing.T) {
 	// Only proceed to init hardware and test if -record flag is passed
 	if !*record {
 		t.SkipNow()
 	}
 	host.Init()
 	i2cBus, err := i2c.New(-1)
 	if err != nil {
 		t.Fatal(err)
 	}
 	owBus, err := ds248x.New(i2cBus, nil)
 	if err != nil {
 		t.Fatal(err)
 	}
 	devices, err := owBus.Search(false)
 	if err != nil {
 		t.Fatal(err)
 	}
 	addrs := "1-wire devices found:"
 	for _, a := range devices {
 		addrs += fmt.Sprintf(" %#016x", a)
 	}
 	t.Log(addrs)
 	// See whether there's a ds18b20 on the bus.
 	var addr onewire.Address
 	for _, a := range devices {
 		if a&0xff == 0x28 {
 			addr = a
 			break
 		}
 	}
 	if addr == 0 {
 		t.Fatal("no DS18B20 found")
 	}
 	t.Logf("var addr onewire.Address = %#016x", addr)
 	// Start recording and perform a temperature conversion.
 	rec := &onewiretest.Record{Bus: owBus}
 	time.Sleep(50 * time.Millisecond)
 	ds18b20, err := New(rec, addr, 10)
 	if err != nil {
 		t.Fatalf("ds18b20 init: %s", err)
 	}
 	temp, err := ds18b20.Temperature()
 	if err != nil {
 		t.Fatal(err)
 	}
 	// Output what got recorded.
 	t.Log("var ops = []onewiretest.IO{")
 	for _, op := range rec.Ops {
 		t.Logf("  %#v,", op)
 	}
 	t.Log("}")
 	t.Logf("var temp devices.Celsius = %d // %s", temp, temp.String())
 }
 //
 var record *bool
 func init() {
 	record = flag.Bool("record", false, "record real hardware accesses")
 }
 */
--- a/experimental/devices/ds248x/dev.go
+++ b/experimental/devices/ds248x/dev.go
@ -0,0 +1,186 @@
 // Copyright 2016 The Periph Authors. All rights reserved.
 // Use of this source code is governed under the Apache License, Version 2.0
 // that can be found in the LICENSE file.
 package ds248x
 import (
 	"fmt"
 	"sync"
 	"time"
 	"github.com/google/periph/conn"
 	"github.com/google/periph/experimental/conn/onewire"
 )
 // Dev is a handle to a ds248x device and it implements the onewire.Bus interface.
 //
 // Dev implements a persistent error model: if a fatal error is encountered it places
 // itself into an error state and immediately returns the last error on all subsequent
 // calls. A fresh Dev, which reinitializes the hardware, must be created to proceed.
 //
 // A persistent error is only set when there is a problem with the ds248x device itself
 // (or the I²C bus used to access it). Errors on the 1-wire bus do not cause persistent
 // errors and implement the onewire.BusError interface to indicate this fact.
 type Dev struct {
 	sync.Mutex               // lock for the bus while a transaction is in progress
 	i2c        conn.Conn     // i2c device handle for the ds248x
 	isDS2483   bool          // true: ds2483, false: ds2482-100
 	confReg    byte          // value written to configuration register
 	tReset     time.Duration // time to perform a 1-wire reset
 	tSlot      time.Duration // time to perform a 1-bit 1-wire read/write
 	err        error         // persistent error, device will no longer operate
 }
 // String
 func (d *Dev) String() string {
 	return fmt.Sprintf("ds248x")
 }
 // Tx performs a bus transaction, sending and receiving bytes, and
 // ending by pulling the bus high either weakly or strongly depending
 // on the value of power.
 //
 // A strong pull-up is typically required to power temperature conversion
 // or EEPROM writes.
 func (d *Dev) Tx(w, r []byte, power onewire.Pullup) error {
 	d.Lock()
 	defer d.Unlock()
 	// Issue 1-wire bus reset.
 	if present, err := d.reset(); err != nil {
 		return err
 	} else if !present {
 		return busError("ds248x: no device present")
 	}
 	// Send bytes onto 1-wire bus.
 	for i, b := range w {
 		if power == onewire.StrongPullup && i == len(w)-1 && len(r) == 0 {
 			// This is the last byte, need to activate strong pull-up.
 			d.i2cTx([]byte{cmdWriteConfig, d.confReg&0xbf | 0x4}, nil)
 		}
 		d.i2cTx([]byte{cmd1WWrite, b}, nil)
 		d.waitIdle(7 * d.tSlot)
 	}
 	// Read bytes from one-wire bus.
 	for i, _ := range r {
 		if power == onewire.StrongPullup && i == len(r)-1 {
 			// This is the last byte, need to activate strong-pull-up
 			d.i2cTx([]byte{cmdWriteConfig, d.confReg&0xbf | 0x4}, nil)
 		}
 		d.i2cTx([]byte{cmd1WRead}, r[i:i+1])
 		d.waitIdle(7 * d.tSlot)
 		d.i2cTx([]byte{cmdSetReadPtr, regRDR}, r[i:i+1])
 	}
 	return d.err
 }
 // Search performs a "search" cycle on the 1-wire bus and returns the
 // addresses of all devices on the bus if alarmOnly is false and of all
 // devices in alarm state if alarmOnly is true.
 //
 // If an error occurs during the search the already-discovered devices are
 // returned with the error.
 func (d *Dev) Search(alarmOnly bool) ([]onewire.Address, error) {
 	return onewire.Search(d, alarmOnly)
 }
 // SearchTriplet performs a single bit search triplet command on the bus,
 // waits for it to complete and returs the outcome.
 //
 // SearchTriplet should not be used directly, use Search instead.
 func (d *Dev) SearchTriplet(direction byte) (onewire.TripletResult, error) {
 	// Send one-wire triplet command.
 	var dir byte
 	if direction != 0 {
 		dir = 0x80
 	}
 	d.i2cTx([]byte{cmd1WTriplet, dir}, nil)
 	// Wait and read status register, concoct result from there.
 	status := d.waitIdle(0 * d.tSlot) // in theory 3*tSlot but it's actually overlapped
 	tr := onewire.TripletResult{
 		GotZero: status&0x20 == 0,
 		GotOne:  status&0x40 == 0,
 		Taken:   status >> 7,
 	}
 	return tr, d.err
 }
 //
 // reset issues a reset signal on the 1-wire bus and returns true if any device
 // responded with a presence pulse.
 func (d *Dev) reset() (bool, error) {
 	// Issue reset.
 	d.i2cTx([]byte{cmd1WReset}, nil)
 	// Wait for reset to complete.
 	status := d.waitIdle(d.tReset)
 	if d.err != nil {
 		return false, d.err
 	}
 	// Detect bus short and turn into 1-wire error
 	if (status & 4) != 0 {
 		return false, shortedBusError("onewire/ds248x: bus has a short")
 	}
 	return (status & 2) != 0, nil
 }
 // i2cTx is a helper function to call i2c.Tx and handle the error by persisting it.
 func (d *Dev) i2cTx(w, r []byte) {
 	if d.err != nil {
 		return
 	}
 	d.err = d.i2c.Tx(w, r)
 }
 // waitIdle waits for the one wire bus to be idle.
 //
 // It initially sleeps for the delay and then polls the status register and
 // sleeps for a tenth of the delay each time the status register indicates
 // that the bus is still busy. The last read status byte is returned.
 //
 // An overall timeout of 3ms is applied to the whole procedure. waitIdle
 // uses the persistent error model and returns 0 if there is an error.
 func (d *Dev) waitIdle(delay time.Duration) byte {
 	if d.err != nil {
 		return 0
 	}
 	// Overall timeout.
 	tOut := time.Now().Add(3 * time.Millisecond)
 	time.Sleep(delay)
 	for {
 		// Read status register.
 		var status [1]byte
 		d.i2cTx(nil, status[:])
 		// If bus idle complete, return status. This also returns if d.err!=nil
 		// because in that case status[0]==0.
 		if (status[0] & 1) == 0 {
 			return status[0]
 		}
 		// If we're timing out return error. This is an error with the ds248x, not with
 		// devices on the 1-wire bus, hence it is persistent.
 		if time.Now().After(tOut) {
 			d.err = fmt.Errorf("ds248x: timeout waiting for bus cycle to finish")
 			return 0
 		}
 		// Try not to hog the kernel thread.
 		time.Sleep(delay / 10)
 	}
 }
 // shortedBusError implements error and onewire.ShortedBusError.
 type shortedBusError string
 func (e shortedBusError) Error() string   { return string(e) }
 func (e shortedBusError) IsShorted() bool { return true }
 func (e shortedBusError) BusError() bool  { return true }
 // busError implements error and onewire.BusError.
 type busError string
 func (e busError) Error() string  { return string(e) }
 func (e busError) BusError() bool { return true }
--- a/experimental/devices/ds248x/ds248x.go
+++ b/experimental/devices/ds248x/ds248x.go
@ -0,0 +1,166 @@
 // Copyright 2016 The Periph Authors. All rights reserved.
 // Use of this source code is governed under the Apache License, Version 2.0
 // that can be found in the LICENSE file.
 // Package ds248x controls a Maxim DS2483 or DS2482-100 1-wire interface chip over I²C.
 //
 // Datasheets
 //
 // https://www.maximintegrated.com/en/products/digital/one-wire/DS2483.html
 //
 // https://www.maximintegrated.com/en/products/interface/controllers-expanders/DS2482-100.html
 package ds248x
 import (
 	"errors"
 	"fmt"
 	"time"
 	"github.com/google/periph/conn/i2c"
 )
 // PupOhm controls the strength of the passive pull-up resistor
 // on the 1-wire data line. The default value is 1000Ω.
 type PupOhm uint8
 const (
 	R500Ω  = 4 // 500Ω passive pull-up resistor
 	R1000Ω = 6 // 1000Ω passive pull-up resistor
 )
 // Opts contains options to pass to the constructor.
 type Opts struct {
 	Addr          uint16 // I²C address, default 0x18
 	PassivePullup bool   // false:use active pull-up, true: disable active pullup
 	// The following options are only available on the ds2483 (not ds2482-100).
 	// The actual value used is the closest possible value (rounded up or down).
 	ResetLow       time.Duration // reset low time, range 440μs..740μs
 	PresenceDetect time.Duration // presence detect sample time, range 58μs..76μs
 	Write0Low      time.Duration // write zero low time, range 52μs..70μs
 	Write0Recovery time.Duration // write zero recovery time, range 2750ns..25250ns
 	PullupRes      PupOhm        // passive pull-up resistance, true: 500Ω, false: 1kΩ
 }
 // New returns an device object that communicates over I²C to the DS2482/DS2483 controller.
 func New(i i2c.Bus, opts *Opts) (*Dev, error) {
 	addr := uint16(0x18)
 	if opts != nil {
 		switch opts.Addr {
 		case 0x18, 0x19, 0x20, 0x21:
 			addr = opts.Addr
 		case 0x00:
 		default:
 			return nil, errors.New("ds248x: given address not supported by device")
 		}
 	}
 	d := &Dev{i2c: &i2c.Dev{Bus: i, Addr: addr}}
 	if err := d.makeDev(opts); err != nil {
 		return nil, err
 	}
 	return d, nil
 }
 //
 // defaults holds default values for optional parameters.
 var defaults = Opts{
 	PassivePullup:  false,
 	ResetLow:       560 * time.Microsecond,
 	PresenceDetect: 68 * time.Microsecond,
 	Write0Low:      64 * time.Microsecond,
 	Write0Recovery: 5250 * time.Nanosecond,
 	PullupRes:      R1000Ω,
 }
 func (d *Dev) makeDev(opts *Opts) error {
 	// Doctor the opts to apply default values.
 	if opts == nil {
 		opts = &defaults
 	}
 	if opts.ResetLow == 0 {
 		opts.ResetLow = defaults.ResetLow
 	}
 	if opts.PresenceDetect == 0 {
 		opts.PresenceDetect = defaults.PresenceDetect
 	}
 	if opts.Write0Low == 0 {
 		opts.Write0Low = defaults.Write0Low
 	}
 	if opts.Write0Recovery == 0 {
 		opts.Write0Recovery = defaults.Write0Recovery
 	}
 	if opts.PullupRes == 0 {
 		opts.PullupRes = defaults.PullupRes
 	}
 	d.tReset = 2 * opts.ResetLow
 	d.tSlot = opts.Write0Low + opts.Write0Recovery
 	// Issue a reset command.
 	if err := d.i2c.Tx([]byte{cmdReset}, nil); err != nil {
 		return fmt.Errorf("ds248x: error while resetting: %s", err)
 	}
 	// Read the status register to confirm that we have a responding ds248x
 	var stat [1]byte
 	if err := d.i2c.Tx([]byte{cmdSetReadPtr, regStatus}, stat[:]); err != nil {
 		return fmt.Errorf("ds248x: error while reading status register: %s", err)
 	}
 	if stat[0] != 0x18 {
 		return fmt.Errorf("ds248x: invalid status register value: %#x, expected 0x18\n", stat[0])
 	}
 	// Write the device configuration register to get the chip out of reset state, immediately
 	// read it back to get confirmation.
 	d.confReg = 0xe1 // standard-speed, no strong pullup, no powerdown, active pull-up
 	if opts.PassivePullup {
 		d.confReg ^= 0x11
 	}
 	var dcr [1]byte
 	if err := d.i2c.Tx([]byte{cmdWriteConfig, d.confReg}, dcr[:]); err != nil {
 		return fmt.Errorf("ds248x: error while writing device config register: %s", err)
 	}
 	// When reading back we only get the bottom nibble
 	if dcr[0] != d.confReg&0x0f {
 		return fmt.Errorf("ds248x: failure to write device config register, wrote %#x got %#x back",
 			d.confReg, dcr[0])
 	}
 	// Set the read ptr to the port configuration register to determine whether we have a
 	// ds2483 vs ds2482-100. This will fail on devices that do not have a port config
 	// register, such as the ds2482-100.
 	d.isDS2483 = d.i2c.Tx([]byte{cmdSetReadPtr, regPCR}, nil) == nil
 	// Set the options for the ds2483.
 	if d.isDS2483 {
 		buf := []byte{cmdAdjPort,
 			byte(0x00 + ((opts.ResetLow/time.Microsecond - 430) / 20 & 0x0f)),
 			byte(0x20 + ((opts.PresenceDetect/time.Microsecond - 55) / 2 & 0x0f)),
 			byte(0x40 + ((opts.Write0Low/time.Microsecond - 51) / 2 & 0x0f)),
 			byte(0x60 + (((opts.Write0Recovery-1250)/2500 + 5) & 0x0f)),
 			byte(0x80 + (opts.PullupRes & 0x0f)),
 		}
 		if err := d.i2c.Tx(buf, nil); err != nil {
 			return fmt.Errorf("ds248x: error while setting port config values: %s", err)
 		}
 	}
 	return nil
 }
 const (
 	cmdReset       = 0xf0 // reset ds248x
 	cmdSetReadPtr  = 0xe1 // set the read pointer
 	cmdWriteConfig = 0xd2 // write the device configuration
 	cmdAdjPort     = 0xc3 // adjust 1-wire port
 	cmd1WReset     = 0xb4 // reset the 1-wire bus
 	cmd1WBit       = 0x87 // perform a single-bit transaction on the 1-wire bus
 	cmd1WWrite     = 0xa5 // perform a byte write on the 1-wire bus
 	cmd1WRead      = 0x96 // perform a byte read on the 1-wire bus
 	cmd1WTriplet   = 0x78 // perform a triplet operation (2 bit reads, a bit write)
 	regDCR    = 0xc3 // read ptr for device configuration register
 	regStatus = 0xf0 // read ptr for status register
 	regRDR    = 0xe1 // read ptr for read-data register
 	regPCR    = 0xb4 // read ptr for port configuration register
 )
--- a/experimental/devices/ds248x/ds248x_test.go
+++ b/experimental/devices/ds248x/ds248x_test.go
@ -0,0 +1,106 @@
 // Copyright 2016 The Periph Authors. All rights reserved.
 // Use of this source code is governed under the Apache License, Version 2.0
 // that can be found in the LICENSE file.
 package ds248x
 import (
 	"fmt"
 	"testing"
 	"github.com/google/periph/conn/i2c"
 	"github.com/google/periph/conn/i2c/i2ctest"
 )
 // TestInit tests the initialization of a ds2483 using a recording.
 func TestInit(t *testing.T) {
 	var ops = []i2ctest.IO{
 		{Addr: 0x18, Write: []byte{0xf0}, Read: []byte(nil)},
 		{Addr: 0x18, Write: []byte{0xe1, 0xf0}, Read: []byte{0x18}},
 		{Addr: 0x18, Write: []byte{0xd2, 0xe1}, Read: []byte{0x1}},
 		{Addr: 0x18, Write: []byte{0xe1, 0xb4}, Read: []byte(nil)},
 		{Addr: 0x18, Write: []byte{0xc3, 0x6, 0x26, 0x46, 0x66, 0x86}, Read: []byte(nil)},
 		{Addr: 0x18, Write: []byte{0x78, 0x0}, Read: []byte(nil)},
 		{Addr: 0x18, Write: []byte{}, Read: []byte{0xe8}},
 	}
 	bus := &i2ctest.Playback{Ops: ops}
 	if _, err := New(bus, nil); err != nil {
 		t.Fatal(err)
 	}
 }
 func Example() {
 	// Open the I²C bus to which the DS248x is connected.
 	i2cBus, err := i2c.New(-1)
 	if err != nil {
 		fmt.Println(err)
 		return
 	}
 	defer i2cBus.Close()
 	// Open the DS248x to get a 1-wire bus.
 	owBus, err := New(i2cBus, nil)
 	if err != nil {
 		fmt.Println(err)
 		return
 	}
 	// Search devices on the bus
 	devices, err := owBus.Search(false)
 	if err != nil {
 		fmt.Println(err)
 		return
 	}
 	fmt.Printf("Found %d 1-wire devices: ", len(devices))
 	for _, d := range devices {
 		fmt.Printf(" %#16x", uint64(d))
 	}
 	fmt.Print('\n')
 }
 /* Commented out in order not to import periph/host, need to move to smoke test
 // TestRecordInit tests and records the initialization of a ds248x by accessing
 // real hardware and outputs the recording ready to use for playback in
 // TestInit.
 //
 // This test is skipped unless the -record flag is passed to the test executable.
 // Use either `go test -args -record` or `ds2483.test -test.v -record`.
 func TestRecordInit(t *testing.T) {
 	// Only proceed to init hardware and test if -record flag is passed
 	if !*record {
 		t.SkipNow()
 	}
 	host.Init()
 	i2cReal, err := i2c.New(-1)
 	if err != nil {
 		t.Fatal(err)
 	}
 	i2cBus := &i2ctest.Record{Bus: i2cReal}
 	// Now init the ds248x.
 	owBus, err := New(i2cBus, nil)
 	if err != nil {
 		t.Fatal(err)
 	}
 	// Perform a search triplet operation to see whether anyone is on the bus
 	// (we could do a full search but that would produce a very long recording).
 	_, err = owBus.SearchTriplet(0)
 	if err != nil {
 		t.Fatal(err)
 	}
 	// Output the recording.
 	t.Logf("var ops = i2ctest.IO{\n")
 	for _, op := range i2cBus.Ops {
 		t.Logf("  {Addr: %#x, Write: %#v, Read: %#v},\n", op.Addr, op.Write, op.Read)
 	}
 	t.Logf("}\n")
 }
 //
 var record *bool
 func init() {
 	record = flag.Bool("record", false, "record real hardware accesses")
 }
 */