v0.7.0: Add Fretboard.chord() method for named chord lookups

New `fb.chord("G")` API lets you look up fingerings by chord name
instead of knowing fret positions upfront. Updates all docs to use
REPL-style examples with verified output.

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>

README.md

@@ -62,6 +62,22 @@ $ pip install pytheory
 ['C major', 'G major', 'A minor', 'F major']
 ```
 
+## Keys and Progressions
+
+```pycon
+>>> from pytheory import Key
+
+>>> key = Key("G", "major")
+>>> key.chords
+['G major', 'A minor', 'B minor', 'C major', 'D major', 'E minor', 'F# diminished']
+
+>>> [c.identify() for c in key.progression("I", "V", "vi", "IV")]
+['G major', 'D major', 'E minor', 'C major']
+
+>>> Key.detect("C", "E", "G", "A", "D")
+<Key C major>
+```
+
 ## Chord Analysis
 
 ```pycon
@@ -116,7 +132,10 @@ $ pip install pytheory
 >>> Fretboard.keyboard(25, "C3")      # 25-key MIDI controller
 
 >>> CHARTS['western']['Am'].fingering(fretboard=Fretboard.guitar())
-(0, 1, 2, 2, 0, 0)
+Fingering(e=0, B=1, G=2, D=2, A=0, E=0)
+
+>>> Fretboard.guitar().fingering(0, 1, 0, 2, 3, 0).identify()
+'C major'
 ```
 
 ## Audio Playback
@@ -127,6 +146,22 @@ $ pip install pytheory
 >>> tone = Tone.from_string("A4", system="western")
 >>> play(tone, t=1_000)                   # sine wave, 1 second
 >>> play(tone, synth=Synth.SAW, t=1_000)  # sawtooth wave
+
+>>> from pytheory import save, Chord
+>>> save(Chord.from_name("Am7"), "am7.wav", t=2_000)  # save to WAV
+```
+
+## Command-Line Interface
+
+```
+$ pytheory tone A4                          # frequency, MIDI, overtones
+$ pytheory chord C E G                      # identify chord from notes
+$ pytheory key G major                      # explore a key
+$ pytheory scale C dorian                   # show a scale
+$ pytheory fingering Am --capo 2            # guitar fingering
+$ pytheory progression C major I V vi IV    # build a progression
+$ pytheory detect C E G A D                 # detect key from notes
+$ pytheory play Am7 --synth triangle        # play a chord
 ```
 
 ## Features
@@ -138,7 +173,7 @@ $ pip install pytheory
 - **25 instrument presets**: guitar (8 tunings), 12-string, bass, mandolin family, violin family, banjo, harp, oud, sitar, shamisen, erhu, charango, pipa, balalaika, lute, pedal steel, keyboard
 - **Pitch tools**: frequency ↔ tone conversion, MIDI ↔ tone, interval naming, circle of fifths, overtone series, transposition
 - **3 temperaments**: equal, Pythagorean, quarter-comma meantone
-- **Audio synthesis**: sine, sawtooth, and triangle wave playback
+- **Audio synthesis**: sine, sawtooth, and triangle wave playback + WAV export
 
 ## Documentation
 

docs/conf.py

@@ -10,7 +10,9 @@ sys.modules["sounddevice"] = MagicMock()
 project = "PyTheory"
 copyright = "2026, Kenneth Reitz"
 author = "Kenneth Reitz"
-release = "0.4.1"
+import pytheory
+release = pytheory.__version__
+version = pytheory.__version__
 
 extensions = [
     "sphinx.ext.autodoc",
@@ -38,7 +40,14 @@ html_theme_options = {
     "github_user": "kennethreitz",
     "github_repo": "pytheory",
     "github_banner": True,
+    "github_button": True,
+    "github_type": "star",
+    "github_count": True,
     "description": "Music Theory for Humans",
+    "extra_nav_links": {
+        f"v{pytheory.__version__}": "https://pypi.org/project/pytheory/",
+    },
+    "show_powered_by": False,
 }
 html_static_path = ["_static"]
 html_extra_path = ["CNAME"]

docs/guide/chords.rst

@@ -127,13 +127,33 @@ Quality       Intervals         Example tones (from C)
    >>> chart["Cm7"].acceptable_tone_names
    ('C', 'D#', 'G', 'A#')    # Eb and Bb shown as sharps
 
-Building Chords Manually
--------------------------
+Building Chords
+---------------
+
+Several convenience constructors make chord creation concise:
 
 .. code-block:: python
 
-   from pytheory import Tone, Chord
+   from pytheory import Chord
 
+   # From note names (simplest)
+   Chord.from_tones("C", "E", "G")           # <Chord C major>
+   Chord.from_tones("A", "C", "E")           # <Chord A minor>
+
+   # From a chord name (uses the built-in chart)
+   Chord.from_name("Am7")                    # <Chord A minor 7th>
+   Chord.from_name("G7")                     # <Chord G dominant 7th>
+
+   # From root + semitone intervals
+   Chord.from_intervals("C", 4, 7)           # <Chord C major>
+   Chord.from_intervals("D", 3, 7)           # <Chord D minor>
+   Chord.from_intervals("G", 4, 7, 10)       # <Chord G dominant 7th>
+
+   # From MIDI note numbers
+   Chord.from_midi_message(60, 64, 67)       # <Chord C major>
+
+   # Full manual construction
+   from pytheory import Tone
    c_major = Chord(tones=[
        Tone.from_string("C4", system="western"),
        Tone.from_string("E4", system="western"),
@@ -238,6 +258,39 @@ you hear a pulsing at the **beat frequency**: ``|f1 - f2|`` Hz.
    # The slowest (most perceptible) beat
    chord.beat_pulse  # 189.6 Hz
 
+Transposition
+-------------
+
+Shift an entire chord up or down by any number of semitones:
+
+.. code-block:: python
+
+   >>> Chord.from_name("C").transpose(7).identify()
+   'G major'
+
+   >>> Chord.from_name("Am7").transpose(-2).identify()
+   'G minor 7th'
+
+Chord Manipulation
+------------------
+
+Add or remove individual tones from a chord:
+
+.. code-block:: python
+
+   from pytheory import Chord, Tone
+
+   c_major = Chord.from_tones("C", "E", "G")
+
+   # Add a tone to build a seventh chord
+   b4 = Tone.from_string("B4", system="western")
+   cmaj7 = c_major.add_tone(b4)
+   cmaj7.identify()     # 'C major 7th'
+
+   # Remove a tone
+   c_again = cmaj7.remove_tone("B")
+   c_again.identify()   # 'C major'
+
 Chord Identification
 --------------------
 
@@ -247,23 +300,25 @@ against 17 known chord types (triads, 7ths, 9ths, sus, power chords).
 
 .. code-block:: python
 
-   from pytheory import Chord, Tone
+   from pytheory import Chord
 
-   # Build a chord and identify it
-   chord = Chord([
-       Tone.from_string("A4", system="western"),
-       Tone.from_string("C5", system="western"),
-       Tone.from_string("E5", system="western"),
-   ])
-   chord.identify()   # 'A minor'
+   # From note names
+   Chord.from_tones("A", "C", "E").identify()        # 'A minor'
+   Chord.from_tones("G", "B", "D", "F").identify()   # 'G dominant 7th'
 
    # Works with any voicing or inversion
-   chord2 = Chord([
-       Tone.from_string("E4", system="western"),
-       Tone.from_string("G4", system="western"),
-       Tone.from_string("C5", system="western"),
-   ])
-   chord2.identify()  # 'C major' (first inversion detected)
+   Chord.from_tones("E", "G", "C").identify()         # 'C major'
+
+   # Flats work too
+   Chord.from_tones("Bb", "D", "F").identify()        # 'Bb major'
+
+You can also access the root and quality separately:
+
+.. code-block:: python
+
+   chord = Chord.from_name("Am7")
+   chord.root         # <Tone A4>
+   chord.quality       # 'minor 7th'
 
 Harmonic Analysis
 -----------------
@@ -334,6 +389,29 @@ gold standard — every voice moves by step whenever possible.
        print(f"{src} -> {dst}  ({motion:+d} semitones)")
    # Each voice moves the minimum distance to reach the target chord
 
+Tritone Substitution
+--------------------
+
+In jazz harmony, any `dominant chord <https://en.wikipedia.org/wiki/Dominant_seventh_chord>`_
+can be replaced by the dominant chord a
+`tritone <https://en.wikipedia.org/wiki/Tritone_substitution>`_ (6
+semitones) away. This works because the two chords share the same
+tritone interval — the 3rd and 7th simply swap roles.
+
+Common tritone subs: G7 <-> Db7, C7 <-> F#7, D7 <-> Ab7.
+
+.. code-block:: python
+
+   from pytheory import Chord
+
+   g7 = Chord.from_name("G7")
+   sub = g7.tritone_sub()
+   sub.identify()       # 'C# dominant 7th' (enharmonic Db7)
+
+   # Both resolve to C — try them in a ii-V-I:
+   #   Dm7 → G7  → Cmaj7   (standard)
+   #   Dm7 → Db7 → Cmaj7   (with tritone sub — chromatic bass line!)
+
 The Overtone Series
 -------------------
 

docs/guide/cli.rst

@@ -0,0 +1,129 @@
+Command-Line Interface
+======================
+
+PyTheory includes a CLI for quick music theory lookups from the terminal.
+
+Tone Lookup
+-----------
+
+Look up any note's frequency, MIDI number, enharmonic spelling, and
+overtones::
+
+    $ pytheory tone A4
+      Note:        A4
+      Frequency:   440.00 Hz (equal temperament)
+      MIDI:        69
+      Overtones:   440.0, 880.0, 1320.0, 1760.0, 2200.0, 2640.0
+
+Compare temperaments with ``--temperament``::
+
+    $ pytheory tone C5 --temperament pythagorean
+      Note:        C5
+      Frequency:   521.48 Hz (pythagorean temperament)
+      Equal temp:  523.25 Hz (diff: -5.9 cents)
+
+Scale Display
+-------------
+
+Show any scale in any system::
+
+    $ pytheory scale C major
+      C major: C D E F G A B C
+      Intervals:  C4 -2- D4 -2- E4 -1- F4 -2- G4 -2- A4 -2- B4 -1- C5
+
+    $ pytheory scale C dorian
+    $ pytheory scale Sa bhairav --system indian
+
+Chord Identification
+--------------------
+
+Identify a chord from its notes::
+
+    $ pytheory chord C E G
+      Chord:     C major
+      Tones:     C4 E4 G4
+      Intervals: [4, 3]
+      Harmony:   0.5833
+      Dissonance: 0.0712
+      Tension:   0.00 (tritones=0)
+
+    $ pytheory chord G B D F
+      Chord:     G dominant 7th
+
+Key Explorer
+------------
+
+Get a complete breakdown of any key — signature, diatonic triads,
+seventh chords, relative and parallel keys::
+
+    $ pytheory key G major
+      Key: G major
+      Signature: 1 sharps, 0 flats (F#)
+      Scale: G A B C D E F#
+      Triads:
+        I       G major
+        ii      A minor
+        iii     B minor
+        IV      C major
+        V       D major
+        vi      E minor
+        vii°    F# diminished
+      7th chords:
+        G major 7th
+        A minor 7th
+        ...
+      Relative: <Key E minor>
+      Parallel: <Key G minor>
+
+Guitar Fingerings
+-----------------
+
+Get tablature for any of the 144 built-in chords::
+
+    $ pytheory fingering Am
+    Am
+    E|--0--
+    B|--1--
+    G|--2--
+    D|--2--
+    A|--0--
+    E|--0--
+
+Use ``--capo`` to see fingerings with a capo::
+
+    $ pytheory fingering G --capo 2
+
+Chord Progressions
+------------------
+
+Build progressions from Roman numerals::
+
+    $ pytheory progression G major I V vi IV
+      Key: G major
+      Progression: I → V → vi → IV
+
+        I       G major
+        V       D major
+        vi      E minor
+        IV      C major
+
+Key Detection
+-------------
+
+Detect the most likely key from a set of notes::
+
+    $ pytheory detect C E G A D
+      Detected key: C major
+      Scale: C D E F G A B C
+
+Audio Playback
+--------------
+
+Play individual notes or chords (requires PortAudio)::
+
+    $ pytheory play A4                         # Single note
+    $ pytheory play C E G                      # Notes as chord
+    $ pytheory play Am7                        # Chord by name
+    $ pytheory play C E G --synth saw          # Sawtooth wave
+    $ pytheory play A4 --duration 2000         # 2 seconds
+    $ pytheory play C E G --temperament meantone

docs/guide/fretboard.rst

@@ -55,6 +55,19 @@ strings, except between G and B which is a major 3rd (4 semitones).
    # Custom tuning with any notes
    Fretboard.guitar(("C4", "G3", "C3", "G2", "C2", "G1"))
 
+**Capo** — a `capo <https://en.wikipedia.org/wiki/Capo>`_ raises all
+strings by a number of frets, letting you play open chord shapes in
+higher keys:
+
+.. code-block:: python
+
+   # Capo on fret 2 — open G shape now sounds as A major
+   fb = Fretboard.guitar(capo=2)
+
+   # Or apply a capo to an existing fretboard
+   fb = Fretboard.guitar()
+   fb_capo3 = fb.capo(3)
+
 The Mandolin Family
 -------------------
 
@@ -172,29 +185,53 @@ on any instrument. It scores each possibility by:
 2. Preferring **ascending** fret patterns — easier hand position
 3. Minimizing the number of **fingers needed**
 
-.. code-block:: python
+.. code-block:: pycon
 
-   from pytheory import Fretboard, CHARTS
+   >>> from pytheory import Fretboard, CHARTS
 
-   fb = Fretboard.guitar()
-   c = CHARTS["western"]["C"]
+   >>> fb = Fretboard.guitar()
+   >>> f = fb.chord("C")
+   >>> f
+   Fingering(e=0, B=1, G=0, D=2, A=3, E=0)
 
-   # Best single fingering
-   print(c.fingering(fretboard=fb))
-   # (0, 1, 0, 2, 3, 0)
+   >>> f['A']
+   3
+   >>> f[1]
+   1
 
-   # All equally-scored fingerings
-   all_c = c.fingering(fretboard=fb, multiple=True)
+   >>> f.identify()
+   'C major'
 
-   # Muted strings appear as None
-   f = CHARTS["western"]["F"]
-   print(f.fingering(fretboard=fb))
+   >>> chord = f.to_chord()
+   >>> chord.identify()
+   'C major'
+
+   >>> # All equally-scored fingerings via CHARTS
+   >>> CHARTS["western"]["C"].fingering(fretboard=fb, multiple=True)
+   [...]
+
+   >>> # Muted strings appear as None
+   >>> CHARTS["western"]["F"].fingering(fretboard=fb)
+   ...
+
+You can also go from fret positions to chord identification:
+
+.. code-block:: pycon
+
+   >>> # "What chord am I playing?"
+   >>> fb = Fretboard.guitar()
+   >>> f = fb.fingering(0, 0, 0, 2, 2, 0)
+   >>> f
+   Fingering(e=0, B=0, G=0, D=2, A=2, E=0)
+   >>> f.identify()
+   'E minor'
 
 Reading Fingerings
 ~~~~~~~~~~~~~~~~~~
 
-The tuple ``(0, 1, 0, 2, 3, 0)`` reads from the highest string to the
-lowest::
+Each position is labeled with its string name. Duplicate string names
+are disambiguated — on a standard guitar, high E appears as ``e`` and
+low E as ``E``::
 
     e|--0--    (open — E)
     B|--1--    (fret 1 — C)
@@ -205,6 +242,22 @@ lowest::
 
 A value of ``None`` means the string is muted (not played).
 
+ASCII Tablature
+~~~~~~~~~~~~~~~
+
+For a more visual representation, use ``tab()``:
+
+.. code-block:: python
+
+   >>> print(CHARTS["western"]["C"].tab(fretboard=fb))
+   C
+   E|--0--
+   B|--1--
+   G|--0--
+   D|--2--
+   A|--3--
+   E|--0--
+
 Generating Full Charts
 ----------------------
 

docs/guide/playback.rst

@@ -25,14 +25,13 @@ Playing a Chord
 
 .. code-block:: python
 
-   from pytheory import Chord, Tone, play
+   from pytheory import Chord, play
 
-   c_major = Chord(tones=[
-       Tone.from_string("C4", system="western"),
-       Tone.from_string("E4", system="western"),
-       Tone.from_string("G4", system="western"),
-   ])
-   play(c_major, t=2_000)  # Play for 2 seconds
+   # From a chord name
+   play(Chord.from_name("Am7"), t=2_000)
+
+   # From note names
+   play(Chord.from_tones("C", "E", "G"), t=2_000)
 
 Waveform Types
 --------------
@@ -78,3 +77,23 @@ Try playing a C major chord in each temperament — you'll hear subtle
 differences in the "color" of the major third. Equal temperament is
 a compromise; the other systems sacrifice some keys to make the good
 keys sound better.
+
+Saving to WAV
+-------------
+
+Render tones or chords to a WAV file instead of playing them live.
+This works even without speakers or PortAudio:
+
+.. code-block:: python
+
+   from pytheory import save, Chord, Tone, Synth
+
+   # Save a single tone
+   save(Tone.from_string("A4"), "a440.wav", t=1_000)
+
+   # Save a chord
+   save(Chord.from_name("Am7"), "am7.wav", t=2_000)
+
+   # Choose waveform and temperament
+   save(Chord.from_name("C"), "c_triangle.wav",
+        synth=Synth.TRIANGLE, temperament="meantone", t=3_000)

docs/guide/quickstart.rst

@@ -8,42 +8,169 @@ Installation
 
    $ pip install pytheory
 
-Basic Usage
------------
+For audio playback, you'll also need `PortAudio <http://www.portaudio.com/>`_:
 
-Create tones, build scales, and explore music theory:
+- macOS: ``brew install portaudio``
+- Ubuntu: ``apt install libportaudio2``
+- Windows: included with the ``sounddevice`` package
+
+Tones
+-----
+
+A :class:`~pytheory.tones.Tone` is a single musical note:
 
 .. code-block:: python
 
-   from pytheory import Tone, TonedScale, Fretboard, CHARTS
+   from pytheory import Tone
 
-   # Create a tone — A4 is the tuning standard (440 Hz)
+   # Create tones — sharps and flats both work
    a4 = Tone.from_string("A4", system="western")
-   print(a4.frequency)  # 440.0
+   a4.frequency    # 440.0 Hz — the tuning standard
 
-   # Tone arithmetic — add semitones to move up the chromatic scale
    c4 = Tone.from_string("C4", system="western")
-   e4 = c4 + 4          # Major third up (4 semitones)
-   g4 = c4 + 7          # Perfect fifth up (7 semitones)
-   print(e4, g4)         # E4 G4
+   c4.midi         # 60 — middle C
 
-   # Measure intervals between tones
-   print(g4 - c4)        # 7 (semitones — a perfect fifth)
+   # From a frequency or MIDI number
+   Tone.from_frequency(440)    # <Tone A4>
+   Tone.from_midi(60)          # <Tone C4>
 
-   # Build a C major scale
-   c_major = TonedScale(tonic="C4")["major"]
-   print(c_major.note_names)
+   # Tone arithmetic
+   c4 + 4          # <Tone E4> — major third up
+   c4 + 7          # <Tone G4> — perfect fifth up
+
+   # Interval between two tones
+   g4 = c4 + 7
+   g4 - c4         # 7 semitones
+   c4.interval_to(g4)  # 'perfect 5th'
+
+   # Enharmonics
+   Tone.from_string("C#4", system="western").enharmonic  # 'Db'
+
+Scales
+------
+
+Build scales in any key and mode:
+
+.. code-block:: python
+
+   from pytheory import TonedScale
+
+   c = TonedScale(tonic="C4")
+
+   c["major"].note_names
    # ['C', 'D', 'E', 'F', 'G', 'A', 'B', 'C']
 
-   # Build diatonic triads from the scale
-   I  = c_major.triad(0)   # C E G  (C major)
-   IV = c_major.triad(3)   # F A C  (F major)
-   V  = c_major.triad(4)   # G B D  (G major)
+   c["minor"].note_names
+   # ['C', 'D', 'D#', 'F', 'G', 'G#', 'A#', 'C']
 
-   # Guitar chord fingerings
-   fb = Fretboard.guitar()
-   fingering = CHARTS["western"]["Am"].fingering(fretboard=fb)
-   print(fingering)  # (0, 1, 2, 2, 0, 0)
+   c["dorian"].note_names
+   # ['C', 'D', 'D#', 'F', 'G', 'A', 'A#', 'C']
+
+   # Access scale degrees by name or numeral
+   major = c["major"]
+   major["tonic"]       # C4
+   major["dominant"]    # G4
+   major["V"]           # G4
+
+Keys and Chords
+---------------
+
+The :class:`~pytheory.scales.Key` class ties everything together —
+scales, chords, and progressions:
+
+.. code-block:: python
+
+   from pytheory import Key
+
+   key = Key("G", "major")
+   key.note_names    # ['G', 'A', 'B', 'C', 'D', 'E', 'F#', 'G']
+
+   # All diatonic triads
+   key.chords
+   # ['G major', 'A minor', 'B minor', 'C major',
+   #  'D major', 'E minor', 'F# diminished']
+
+   # Build progressions from Roman numerals
+   chords = key.progression("I", "V", "vi", "IV")
+   [c.identify() for c in chords]
+   # ['G major', 'D major', 'E minor', 'C major']
+
+   # Detect the key from notes
+   Key.detect("C", "E", "G", "A", "D")    # <Key C major>
+
+Build chords directly:
+
+.. code-block:: python
+
+   from pytheory import Chord
+
+   Chord.from_tones("C", "E", "G")             # <Chord C major>
+   Chord.from_name("Am7")                       # <Chord A minor 7th>
+   Chord.from_intervals("G", 4, 7, 10)          # <Chord G dominant 7th>
+
+   # Identify any chord
+   Chord.from_tones("Bb", "D", "F").identify()  # 'Bb major'
+
+   # Analyze in a key
+   Chord.from_name("G7").analyze("C")           # 'V7'
+
+Guitar Fingerings
+-----------------
+
+.. code-block:: pycon
+
+   >>> from pytheory import Fretboard
+
+   >>> fb = Fretboard.guitar()
+
+   >>> fb.chord("C")
+   Fingering(e=0, B=1, G=0, D=2, A=3, E=0)
+
+   >>> fb.chord("C")['A']
+   3
+
+   >>> fb.fingering(0, 0, 0, 2, 2, 0).identify()
+   'E minor'
+
+   >>> from pytheory import CHARTS
+   >>> print(CHARTS["western"]["Am"].tab(fretboard=fb))
+   Am
+   E|--0--
+   B|--1--
+   G|--2--
+   D|--2--
+   A|--0--
+   E|--0--
+
+Audio Playback
+--------------
+
+.. code-block:: python
+
+   from pytheory import Tone, Chord, play, save, Synth
+
+   # Play a tone
+   play(Tone.from_string("A4"), t=1_000)
+
+   # Play a chord with a different waveform
+   play(Chord.from_name("Am7"), synth=Synth.TRIANGLE, t=2_000)
+
+   # Save to a WAV file
+   save(Chord.from_name("C"), "c_major.wav", t=2_000)
+
+Command Line
+------------
+
+PyTheory also works from the terminal::
+
+   $ pytheory tone A4
+   $ pytheory chord C E G
+   $ pytheory key G major
+   $ pytheory scale C dorian
+   $ pytheory fingering Am
+   $ pytheory progression C major I V vi IV
+   $ pytheory detect C E G A D
+   $ pytheory play Am7 --synth triangle
 
 What's Included
 ---------------
@@ -54,9 +181,13 @@ What's Included
   10 maqamat, 6 Japanese pentatonic scales, blues, pentatonic,
   slendro, pelog, and more
 - **Pitch calculation** in equal, Pythagorean, and meantone temperaments
+- **Chord identification**: name any chord from its notes, intervals, or
+  MIDI numbers (17 chord types recognized)
 - **Chord charts** with 144 pre-built chords (12 roots x 12 qualities)
 - **Chord analysis**: consonance scoring, Plomp-Levelt dissonance,
-  beat frequency calculation
-- **Fingering generation** for guitar (8 tunings), bass, ukulele, or
-  any custom fretted instrument
+  beat frequency calculation, harmonic tension, voice leading
+- **Key detection** and **Roman numeral analysis** (I-IV-V-I progressions)
+- **Fingering generation** for 25 instruments with labeled string names,
+  including guitar (8 tunings), bass, ukulele, mandolin, and more
 - **Audio playback** with sine, sawtooth, and triangle wave synthesis
+- **WAV export** for saving rendered audio to disk

docs/guide/scales.rst

@@ -215,6 +215,35 @@ Some of the most-used chord progressions in Western music:
   My Heart Will Go On)
 - **I–IV–vi–V** — axis of awesome (many, many pop songs)
 
+The :class:`~pytheory.scales.Key` class makes working with progressions
+easy:
+
+.. code-block:: python
+
+   from pytheory import Key
+
+   key = Key("G", "major")
+
+   # Build a progression from Roman numerals
+   chords = key.progression("I", "V", "vi", "IV")
+   for c in chords:
+       print(c.identify())
+   # G major, D major, E minor, C major
+
+   # Nashville number system (same thing, with integers)
+   key.nashville(1, 5, 6, 4)
+
+   # All diatonic triads in the key
+   key.chords
+   # ['G major', 'A minor', 'B minor', 'C major', ...]
+
+   # All diatonic seventh chords
+   key.seventh_chords
+   # ['G major 7th', 'A minor 7th', ...]
+
+   # Detect the key from a set of notes
+   Key.detect("C", "E", "G", "A", "D")   # <Key C major>
+
 The 12-Bar Blues
 ~~~~~~~~~~~~~~~~
 
@@ -245,23 +274,101 @@ structure. In the key of A::
    # The 12-bar blues progression
    blues_12 = [I, I, I, I, IV, IV, I, I, V, IV, I, V]
 
-Parallel Major and Minor
-~~~~~~~~~~~~~~~~~~~~~~~~~
+Key Signatures
+~~~~~~~~~~~~~~
 
-Two scales are **relative** if they share the same notes (C major and
-A minor). Two scales are `parallel <https://en.wikipedia.org/wiki/Parallel_key>`_ if they share the same tonic but
-have different notes (C major and C minor).
+The ``signature`` property tells you how many sharps or flats a key has:
 
-Mixing parallel major and minor is a powerful compositional tool —
-borrowing chords from the parallel minor in a major key creates
-dramatic color shifts. The bVI and bVII chords (Ab and Bb in C major)
-are borrowed from C minor and appear constantly in rock and film music.
+.. code-block:: python
+
+   >>> Key("G", "major").signature
+   {'sharps': 1, 'flats': 0, 'accidentals': ['F#']}
+
+   >>> Key("F", "major").signature
+   {'sharps': 0, 'flats': 1, 'accidentals': ['Bb']}
+
+   >>> Key("C", "major").signature
+   {'sharps': 0, 'flats': 0, 'accidentals': []}
+
+Relative and Parallel Keys
+~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Two keys are **relative** if they share the same notes (C major and
+A minor). Two keys are `parallel <https://en.wikipedia.org/wiki/Parallel_key>`_ if they share the same tonic but
+have different notes (C major and C minor):
+
+.. code-block:: python
+
+   >>> Key("C", "major").relative
+   <Key A minor>
+
+   >>> Key("A", "minor").relative
+   <Key C major>
+
+   >>> Key("C", "major").parallel
+   <Key C minor>
+
+Borrowed Chords
+~~~~~~~~~~~~~~~
+
+`Modal interchange <https://en.wikipedia.org/wiki/Borrowed_chord>`_ —
+borrowing chords from the parallel key — is one of the most powerful
+tools in songwriting. The bVI and bVII chords (Ab and Bb in C major)
+are borrowed from C minor and appear constantly in rock and film music:
+
+.. code-block:: python
+
+   >>> Key("C", "major").borrowed_chords
+   # Chords from C minor that aren't in C major
+
+Secondary Dominants
+~~~~~~~~~~~~~~~~~~~
+
+A `secondary dominant <https://en.wikipedia.org/wiki/Secondary_dominant>`_
+is the V chord *of* a non-tonic chord. It creates a momentary pull
+toward that chord, adding harmonic color:
+
+.. code-block:: python
+
+   key = Key("C", "major")
+
+   # V/V — the dominant of the dominant (D7 → G)
+   key.secondary_dominant(5)     # D dominant 7th
+
+   # V/ii — the dominant of the supertonic (A7 → Dm)
+   key.secondary_dominant(2)     # A dominant 7th
+
+Random Progressions
+~~~~~~~~~~~~~~~~~~~
+
+Need inspiration? Generate weighted random progressions. The weights
+favor common chord functions (I and vi most likely, vii least):
+
+.. code-block:: python
+
+   key = Key("C", "major")
+   chords = key.random_progression(4)    # 4 chords
+   [c.identify() for c in chords]
+   # e.g. ['C major', 'F major', 'A minor', 'G major']
+
+All Keys
+~~~~~~~~
+
+Enumerate all 24 major and minor keys:
+
+.. code-block:: python
+
+   >>> Key.all_keys()
+   [<Key C major>, <Key C minor>, <Key C# major>, <Key C# minor>, ...]
+
+Scale Transposition
+~~~~~~~~~~~~~~~~~~~
+
+Transpose an entire scale by a number of semitones:
 
 .. code-block:: python
 
    c_major = TonedScale(tonic="C4")["major"]
-   c_minor = TonedScale(tonic="C4")["minor"]
-
-   # Compare: same tonic, different notes
-   c_major.note_names  # ['C', 'D', 'E', 'F', 'G', 'A', 'B', 'C']
-   c_minor.note_names  # ['C', 'D', 'D#', 'F', 'G', 'G#', 'A#', 'C']
+   d_major = c_major.transpose(2)    # Up a whole step
+   d_major.note_names
+   # ['D', 'E', 'F#', 'G', 'A', 'B', 'C#', 'D']

docs/guide/tones.rst

@@ -44,9 +44,10 @@ Creating Tones
 
    from pytheory import Tone
 
-   # From a string (most common)
+   # From a string (most common) — sharps and flats both work
    c4 = Tone.from_string("C4")
    cs4 = Tone.from_string("C#4")
+   db4 = Tone.from_string("Db4")     # Same pitch as C#4
 
    # Direct construction
    d = Tone(name="D", octave=3)
@@ -54,20 +55,32 @@ Creating Tones
    # With a specific system
    a4 = Tone.from_string("A4", system="western")
 
+   # From a frequency (finds the nearest note)
+   Tone.from_frequency(440)           # <Tone A4>
+   Tone.from_frequency(261.63)        # <Tone C4>
+
+   # From a MIDI note number
+   Tone.from_midi(60)                 # <Tone C4> (middle C)
+   Tone.from_midi(69)                 # <Tone A4>
+
 Properties
 ----------
 
 .. code-block:: python
 
-   >>> c4 = Tone.from_string("C4")
+   >>> c4 = Tone.from_string("C4", system="western")
    >>> c4.name
    'C'
    >>> c4.octave
    4
    >>> c4.full_name
    'C4'
-   >>> str(c4)
-   'C4'
+   >>> c4.letter       # Note letter without accidentals
+   'C'
+   >>> c4.midi         # MIDI note number
+   60
+   >>> c4.exists       # Is this note in the system?
+   True
 
 Pitch and Frequency
 -------------------
@@ -125,9 +138,47 @@ same note name:
    >>> c5.pitch(temperament="pythagorean")
    521.48   # Slightly different!
 
-   # Symbolic output (SymPy expression)
+Symbolic Pitch
+~~~~~~~~~~~~~~
+
+Pass ``symbolic=True`` to get exact pitch ratios as
+`SymPy <https://en.wikipedia.org/wiki/SymPy>`_ expressions instead of
+floating-point approximations. This is useful for mathematical analysis,
+proving tuning relationships, or comparing temperaments with exact
+arithmetic.
+
+.. code-block:: python
+
+   >>> a4 = Tone.from_string("A4", system="western")
+
+   # Equal temperament: irrational ratios (roots of 2)
    >>> a4.pitch(symbolic=True)
    440
+   >>> Tone.from_string("C5", system="western").pitch(symbolic=True)
+   440*2**(1/4)
+
+   # Pythagorean: pure rational ratios (powers of 3/2)
+   >>> Tone.from_string("G4", system="western").pitch(
+   ...     temperament="pythagorean", symbolic=True)
+   660
+
+   # Compare the major third across temperaments
+   >>> e4 = Tone.from_string("E4", system="western")
+   >>> e4.pitch(temperament="equal", symbolic=True)
+   440*2**(1/3)
+   >>> e4.pitch(temperament="pythagorean", symbolic=True)
+   12160/27
+   >>> e4.pitch(temperament="meantone", symbolic=True)
+   550
+
+   # Symbolic expressions can be evaluated to any precision
+   >>> e4.pitch(symbolic=True).evalf(50)
+   329.62755691286991583007431157433859631791591649985
+
+The symbolic output reveals *why* temperaments differ: equal temperament
+uses irrational numbers (roots of 2), Pythagorean uses powers of 3/2
+(rational but accumulating error), and meantone tunes thirds to the
+pure 5/4 ratio (sacrificing fifths).
 
 Intervals and Arithmetic
 -------------------------
@@ -178,6 +229,58 @@ Subtracting two tones gives the semitone distance:
    >>> c5 - c4       # Octave = 12 semitones
    12
 
+Naming Intervals
+~~~~~~~~~~~~~~~~
+
+The ``interval_to`` method gives the musical name of the interval
+between two tones, including compound intervals that span more than
+one octave:
+
+.. code-block:: python
+
+   >>> c4.interval_to(g4)
+   'perfect 5th'
+   >>> c4.interval_to(c4 + 4)
+   'major 3rd'
+   >>> c4.interval_to(c5)
+   'octave'
+
+   # Compound intervals (more than an octave)
+   >>> c4.interval_to(c4 + 19)    # Octave + perfect 5th
+   'perfect 5th + 1 octave'
+
+Transposition
+~~~~~~~~~~~~~
+
+The ``transpose`` method returns a new tone shifted by a number of
+semitones — equivalent to the ``+`` operator but reads more clearly
+in some contexts:
+
+.. code-block:: python
+
+   >>> c4.transpose(7)     # Same as c4 + 7
+   <Tone G4>
+   >>> c4.transpose(-2)    # Two semitones down
+   <Tone A#3>
+
+MIDI
+~~~~
+
+Every tone maps to a `MIDI note number <https://en.wikipedia.org/wiki/MIDI>`_
+(0–127), the standard for communicating with synthesizers, DAWs, and
+digital instruments:
+
+.. code-block:: python
+
+   >>> c4.midi
+   60          # Middle C
+   >>> Tone.from_string("A4", system="western").midi
+   69          # Concert A
+
+   # Round-trip: MIDI → Tone → MIDI
+   >>> Tone.from_midi(60).midi
+   60
+
 Comparison and Sorting
 ----------------------
 
@@ -248,12 +351,19 @@ D major scale is D E F# G A B C# — not D E Gb G A B Db, even though
 F#=Gb and C#=Db.
 
 PyTheory uses sharps by default (following the tone list ordering), but
-tones carry their enharmonic equivalents:
+every tone knows its enharmonic spelling:
 
 .. code-block:: python
 
-   >>> Tone.from_tuple(("C#", "Db")).names()
-   ['C#', 'Db']
+   >>> Tone.from_string("C#4", system="western").enharmonic
+   'Db'
+
+   >>> Tone.from_string("A#4", system="western").enharmonic
+   'Bb'
+
+   # Natural notes have no enharmonic
+   >>> Tone.from_string("C4", system="western").enharmonic is None
+   True
 
 The Circle of Fifths
 --------------------
@@ -265,11 +375,15 @@ to the starting note:
 
 .. code-block:: python
 
-   >>> t = Tone.from_string("C4", system="western")
-   >>> for i in range(12):
-   ...     print(t.name, end=" ")
-   ...     t = t + 7
-   C G D A E B F# C# G# D# A# F
+   >>> c4 = Tone.from_string("C4", system="western")
+
+   # Clockwise — ascending fifths (adds sharps)
+   >>> [t.name for t in c4.circle_of_fifths()]
+   ['C', 'G', 'D', 'A', 'E', 'B', 'F#', 'C#', 'G#', 'D#', 'A#', 'F']
+
+   # Counter-clockwise — ascending fourths (adds flats)
+   >>> [t.name for t in c4.circle_of_fourths()]
+   ['C', 'F', 'A#', 'D#', 'G#', 'C#', 'F#', 'B', 'E', 'A', 'D', 'G']
 
 Each step clockwise adds one sharp to the key signature; each step
 counter-clockwise (ascending by fourths = 5 semitones) adds one flat.

docs/index.rst

@@ -1,26 +1,69 @@
 PyTheory: Music Theory for Humans
 =================================
 
-**PyTheory** is a Python library that makes exploring music theory approachable.
-Work with tones, scales, chords, and fretboards using a clean, Pythonic API.
+**PyTheory** is a Python library that makes exploring music theory
+approachable and fun. Work with tones, scales, chords, keys, and
+instruments using a clean, Pythonic API.
 
-.. code-block:: python
+::
 
-   from pytheory import TonedScale, Fretboard, CHARTS
+   $ pip install pytheory
 
-   # Build a C major scale
-   c_major = TonedScale(tonic="C4")["major"]
-   print(c_major.note_names)
-   # ['C', 'D', 'E', 'F', 'G', 'A', 'B', 'C']
+.. code-block:: pycon
 
-   # Build a triad from the scale
-   chord = c_major.triad(0)  # C major triad
-   for tone in chord:
-       print(f"{tone}: {tone.frequency:.1f} Hz")
+   >>> from pytheory import Key, Chord, Tone, Fretboard
 
-   # Get guitar fingerings
-   fb = Fretboard.guitar()
-   print(CHARTS["western"]["C"].fingering(fretboard=fb))
+   >>> key = Key("C", "major")
+   >>> key.chords
+   ['C major', 'D minor', 'E minor', 'F major',
+    'G major', 'A minor', 'B diminished']
+
+   >>> [c.identify() for c in key.progression("I", "V", "vi", "IV")]
+   ['C major', 'G major', 'A minor', 'F major']
+
+   >>> Chord.from_tones("Bb", "D", "F").identify()
+   'Bb major'
+
+   >>> c4 = Tone.from_string("C4", system="western")
+   >>> c4.interval_to(c4 + 7)
+   'perfect 5th'
+
+   >>> fb = Fretboard.guitar()
+   >>> fb.chord("G")
+   Fingering(e=3, B=0, G=0, D=0, A=2, E=3)
+
+It also works from the command line::
+
+   $ pytheory key G major
+     Key: G major
+     Signature: 1 sharps, 0 flats (F#)
+     Scale: G A B C D E F# G
+     ...
+
+   $ pytheory chord C E G
+     Chord:     C major
+     Tones:     C4 E4 G4
+     Intervals: [4, 3]
+     ...
+
+   $ pytheory play Am7 --synth triangle
+     Playing: A minor 7th (A4 C4 E4 G4)
+     Synth:   triangle
+
+Highlights
+----------
+
+- **Tones**: frequencies, MIDI, intervals, transposition, circle of fifths,
+  overtone series, 3 temperaments (equal, Pythagorean, meantone)
+- **Scales**: 40+ scales across 6 musical systems — Western, Indian,
+  Arabic, Japanese, Blues, Javanese Gamelan
+- **Chords**: 17 chord types identified automatically, Roman numeral
+  analysis, tension scoring, voice leading, consonance/dissonance
+- **Keys**: key detection, signatures, progressions (Roman numerals and
+  Nashville numbers), borrowed chords, secondary dominants
+- **Instruments**: 25 presets (guitar, bass, ukulele, mandolin, violin,
+  banjo, oud, sitar, erhu, and more) with fingering generation
+- **Audio**: sine, sawtooth, and triangle wave playback + WAV export
 
 .. toctree::
    :maxdepth: 2
@@ -34,6 +77,7 @@ Work with tones, scales, chords, and fretboards using a clean, Pythonic API.
    guide/fretboard
    guide/systems
    guide/playback
+   guide/cli
 
 .. toctree::
    :maxdepth: 2

examples/chord_identifier.py

@@ -0,0 +1,46 @@
+"""Identify chords from notes or guitar fingerings."""
+
+from pytheory import Chord, Fretboard
+
+print("=== Chord Identification from Notes ===")
+print()
+
+test_chords = [
+    ("C", "E", "G"),
+    ("A", "C", "E"),
+    ("G", "B", "D", "F"),
+    ("D", "F#", "A"),
+    ("Bb", "D", "F"),
+    ("E", "G#", "B"),
+    ("C", "Eb", "Gb"),
+    ("C", "G"),
+    ("C", "F", "G"),
+    ("C", "D", "G"),
+]
+
+for notes in test_chords:
+    chord = Chord.from_tones(*notes)
+    name = chord.identify() or "Unknown"
+    print(f"  {', '.join(notes):20s}  →  {name}")
+
+print()
+print("=== Chord Identification from Guitar Fingerings ===")
+print()
+
+fb = Fretboard.guitar()
+
+# Common guitar chord shapes
+shapes = [
+    ("Open C",    (0, 1, 0, 2, 3, 0)),
+    ("Open G",    (3, 0, 0, 0, 2, 3)),
+    ("Open D",    (2, 3, 2, 0, 0, 0)),
+    ("Open Am",   (0, 1, 2, 2, 0, 0)),
+    ("Open Em",   (0, 0, 0, 2, 2, 0)),
+    ("Barre F",   (1, 1, 2, 3, 3, 1)),
+    ("Power E5",  (0, 0, 0, 0, 2, 0)),
+]
+
+for label, positions in shapes:
+    f = fb.fingering(*positions)
+    name = f.identify() or "Unknown"
+    print(f"  {label:12s}  {f}  →  {name}")

examples/chord_tension.py

@@ -0,0 +1,52 @@
+"""Analyze harmonic tension and resolution across chords."""
+
+from pytheory import Chord
+
+print("Chord Tension Analysis")
+print("=" * 70)
+print()
+print(f"{'Chord':>20s}  {'Tension':>8s}  {'Harmony':>8s}  {'Dissonance':>11s}  {'Notes'}")
+print(f"{'─' * 20}  {'─' * 8}  {'─' * 8}  {'─' * 11}  {'─' * 15}")
+
+chords = [
+    # Stable chords
+    "C", "Am",
+    # Moderate tension
+    "Dm7", "Cmaj7",
+    # High tension
+    "G7", "Bdim",
+    # Extended
+    "Am7", "Cmaj9",
+]
+
+for name in chords:
+    chord = Chord.from_name(name)
+    t = chord.tension
+    tones = " ".join(tone.name for tone in chord.tones)
+    print(
+        f"{name:>20s}  {t['score']:>8.2f}  {chord.harmony:>8.4f}"
+        f"  {chord.dissonance:>11.4f}  {tones}"
+    )
+
+# Show the V7 → I resolution
+print()
+print("─" * 70)
+print()
+print("The V7 → I resolution (the strongest pull in tonal music):")
+print()
+
+g7 = Chord.from_name("G7")
+c = Chord.from_name("C")
+
+print(f"  G7 (dominant):  tension={g7.tension['score']:.2f}  "
+      f"tritones={g7.tension['tritones']}  "
+      f"dominant_function={g7.tension['has_dominant_function']}")
+print(f"  C  (tonic):     tension={c.tension['score']:.2f}  "
+      f"tritones={c.tension['tritones']}  "
+      f"dominant_function={c.tension['has_dominant_function']}")
+
+print()
+print("Voice leading (G7 → C):")
+for src, dst, motion in g7.voice_leading(c):
+    direction = "↑" if motion > 0 else "↓" if motion < 0 else "="
+    print(f"  {src.name:3s} → {dst.name:3s}  ({direction} {abs(motion)} semitones)")

examples/circle_of_fifths.py

@@ -0,0 +1,34 @@
+"""Visualize the circle of fifths with key signatures."""
+
+from pytheory import Tone, Key
+
+c = Tone.from_string("C4", system="western")
+
+print("╔══════════════════════════════════════════════╗")
+print("║          THE CIRCLE OF FIFTHS                ║")
+print("╠══════════════════════════════════════════════╣")
+print("║  Key     Sig    Accidentals                  ║")
+print("╠══════════════════════════════════════════════╣")
+
+for tone in c.circle_of_fifths():
+    key = Key(tone.name, "major")
+    sig = key.signature
+    relative = key.relative
+
+    if sig["sharps"]:
+        mark = f'{sig["sharps"]}#'
+    elif sig["flats"]:
+        mark = f'{sig["flats"]}b'
+    else:
+        mark = "--"
+
+    accidentals = ", ".join(sig["accidentals"]) if sig["accidentals"] else "none"
+    print(f"║  {tone.name:3s}     {mark:3s}   {accidentals:20s}  rel: {relative.tonic_name} {relative.mode:5s} ║")
+
+print("╚══════════════════════════════════════════════╝")
+
+# Show that 12 fifths returns to the start
+print()
+print("Proof: 12 perfect fifths cycle through all 12 tones")
+names = [t.name for t in c.circle_of_fifths()]
+print(f"  {' → '.join(names)} → {names[0]}")

examples/fretboard_explorer.py

@@ -0,0 +1,74 @@
+"""Explore instruments, tunings, and chord fingerings."""
+
+from pytheory import Fretboard, CHARTS
+
+# ── Compare Instruments ─────────────────────────────────────────────────
+
+print("Instrument Tunings")
+print("=" * 55)
+
+instruments = [
+    ("Guitar (standard)", Fretboard.guitar()),
+    ("Guitar (drop D)",   Fretboard.guitar("drop d")),
+    ("Guitar (open G)",   Fretboard.guitar("open g")),
+    ("Guitar (DADGAD)",   Fretboard.guitar("dadgad")),
+    ("Bass",              Fretboard.bass()),
+    ("Ukulele",           Fretboard.ukulele()),
+    ("Mandolin",          Fretboard.mandolin()),
+    ("Violin",            Fretboard.violin()),
+    ("Banjo",             Fretboard.banjo()),
+    ("Bouzouki (Irish)",  Fretboard.bouzouki()),
+]
+
+for name, fb in instruments:
+    tuning = " ".join(t.full_name for t in fb.tones)
+    print(f"  {name:22s}  {tuning}")
+
+# ── Guitar Chord Chart ──────────────────────────────────────────────────
+
+print()
+print("Guitar Chord Chart (standard tuning)")
+print("=" * 55)
+
+fb = Fretboard.guitar()
+chart = CHARTS["western"]
+
+for chord_name in ["C", "G", "D", "Am", "Em", "F", "A", "E", "Dm", "G7", "C7", "Am7"]:
+    f = chart[chord_name].fingering(fretboard=fb)
+    print(f"  {chord_name:5s}  {f}")
+
+# ── Capo Magic ──────────────────────────────────────────────────────────
+
+print()
+print("Capo Transposition")
+print("=" * 55)
+print("  Playing open chord shapes with a capo changes the key:")
+print()
+
+open_shapes = ["C", "G", "D", "Am", "Em"]
+
+for capo_fret in range(1, 6):
+    fb_capo = Fretboard.guitar(capo=capo_fret)
+    results = []
+    for shape in open_shapes:
+        f = chart[shape].fingering(fretboard=fb_capo)
+        actual = f.identify() or "?"
+        results.append(f"{shape}→{actual.split()[0]}")
+    print(f"  Capo {capo_fret}:  {', '.join(results)}")
+
+# ── Same Chord on Different Instruments ─────────────────────────────────
+
+print()
+print("C Major on Different Instruments")
+print("=" * 55)
+
+c_chord = chart["C"]
+for name, fb in [("Guitar", Fretboard.guitar()),
+                  ("Ukulele", Fretboard.ukulele()),
+                  ("Mandolin", Fretboard.mandolin()),
+                  ("Banjo", Fretboard.banjo())]:
+    try:
+        f = c_chord.fingering(fretboard=fb)
+        print(f"  {name:12s}  {f}")
+    except Exception:
+        print(f"  {name:12s}  (not available for this tuning)")

examples/interval_trainer.py

@@ -0,0 +1,93 @@
+"""Learn intervals — names, sounds, and relationships."""
+
+from pytheory import Tone, Chord, Interval
+
+c4 = Tone.from_string("C4", system="western")
+
+# ── Interval Reference ──────────────────────────────────────────────────
+
+print("Interval Reference (from C4)")
+print("=" * 70)
+print()
+print(f"{'Semitones':>10s}  {'Note':>5s}  {'Interval Name':>18s}  {'Sound / Song'}")
+print(f"{'─' * 10}  {'─' * 5}  {'─' * 18}  {'─' * 30}")
+
+songs = {
+    0:  "Same note",
+    1:  "Jaws",
+    2:  "Happy Birthday",
+    3:  "Greensleeves",
+    4:  "Here Comes the Sun",
+    5:  "Here Comes the Bride",
+    6:  "The Simpsons",
+    7:  "Star Wars (main theme)",
+    8:  "Love Story",
+    9:  "My Bonnie Lies Over the Ocean",
+    10: "Somewhere (West Side Story)",
+    11: "Take On Me (chorus)",
+    12: "Somewhere Over the Rainbow",
+}
+
+for semitones in range(13):
+    tone = c4 + semitones
+    name = c4.interval_to(tone)
+    song = songs.get(semitones, "")
+    print(f"{semitones:>10d}  {tone.name:>5s}  {name:>18s}  {song}")
+
+# ── Interval Constants ──────────────────────────────────────────────────
+
+print()
+print("Interval Constants (pytheory.Interval)")
+print("=" * 40)
+
+constants = [
+    ("UNISON", Interval.UNISON),
+    ("MINOR_SECOND", Interval.MINOR_SECOND),
+    ("MAJOR_SECOND", Interval.MAJOR_SECOND),
+    ("MINOR_THIRD", Interval.MINOR_THIRD),
+    ("MAJOR_THIRD", Interval.MAJOR_THIRD),
+    ("PERFECT_FOURTH", Interval.PERFECT_FOURTH),
+    ("TRITONE", Interval.TRITONE),
+    ("PERFECT_FIFTH", Interval.PERFECT_FIFTH),
+    ("MINOR_SIXTH", Interval.MINOR_SIXTH),
+    ("MAJOR_SIXTH", Interval.MAJOR_SIXTH),
+    ("MINOR_SEVENTH", Interval.MINOR_SEVENTH),
+    ("MAJOR_SEVENTH", Interval.MAJOR_SEVENTH),
+    ("OCTAVE", Interval.OCTAVE),
+]
+
+for name, value in constants:
+    print(f"  Interval.{name:16s} = {value}")
+
+# ── Compound Intervals ─────────────────────────────────────────────────
+
+print()
+print("Compound Intervals (beyond one octave)")
+print("=" * 50)
+
+for semitones in [13, 14, 15, 16, 19, 24]:
+    tone = c4 + semitones
+    name = c4.interval_to(tone)
+    print(f"  {semitones:2d} semitones  {tone.full_name:5s}  {name}")
+
+# ── Consonance Ranking ──────────────────────────────────────────────────
+
+print()
+print("Intervals Ranked by Consonance")
+print("=" * 50)
+
+intervals = []
+for semitones in range(1, 13):
+    tone = c4 + semitones
+    dyad = Chord.from_tones("C", tone.name)
+    name = c4.interval_to(tone)
+    intervals.append((dyad.harmony, dyad.dissonance, semitones, name))
+
+# Sort by harmony score (descending)
+intervals.sort(key=lambda x: x[0], reverse=True)
+
+print(f"{'Rank':>5s}  {'Interval':>18s}  {'Harmony':>8s}  {'Dissonance':>11s}")
+print(f"{'─' * 5}  {'─' * 18}  {'─' * 8}  {'─' * 11}")
+
+for rank, (harmony, dissonance, _, name) in enumerate(intervals, 1):
+    print(f"{rank:>5d}  {name:>18s}  {harmony:>8.4f}  {dissonance:>11.4f}")

examples/key_detection.py

@@ -0,0 +1,64 @@
+"""Detect the key of a melody or chord progression."""
+
+from pytheory import Key, Chord
+
+print("Key Detection")
+print("=" * 55)
+print()
+
+# ── Detect from Melody Notes ────────────────────────────────────────────
+
+melodies = [
+    ("Twinkle Twinkle",    ["C", "G", "A", "F", "E", "D"]),
+    ("Happy Birthday",     ["G", "A", "B", "C", "D", "F#"]),
+    ("Yesterday",          ["F", "E", "D", "C", "Bb", "A", "G"]),
+    ("Minor melody",       ["A", "B", "C", "D", "E", "F", "G"]),
+    ("Blues lick",         ["E", "G", "A", "B", "D"]),
+    ("Chromatic fragment",  ["C", "C#", "D", "D#", "E"]),
+]
+
+print("Detecting key from melody notes:")
+print()
+for label, notes in melodies:
+    key = Key.detect(*notes)
+    print(f"  {label:22s}  {', '.join(notes):30s}  →  {key}")
+
+# ── Detect from Chord Progression ──────────────────────────────────────
+
+print()
+print("Detecting key from chord tones:")
+print()
+
+progressions = [
+    ("I-IV-V",      [("C", "E", "G"), ("F", "A", "C"), ("G", "B", "D")]),
+    ("Pop in G",    [("G", "B", "D"), ("D", "F#", "A"), ("E", "G", "B"), ("C", "E", "G")]),
+    ("Jazz ii-V-I", [("D", "F", "A"), ("G", "B", "D", "F"), ("C", "E", "G", "B")]),
+]
+
+for label, chord_tones in progressions:
+    # Collect all unique note names
+    all_notes = set()
+    for tones in chord_tones:
+        all_notes.update(tones)
+
+    key = Key.detect(*all_notes)
+    chord_names = [Chord.from_tones(*t).identify() for t in chord_tones]
+    print(f"  {label:15s}  {' → '.join(chord_names):40s}  →  {key}")
+
+# ── All 24 Keys ─────────────────────────────────────────────────────────
+
+print()
+print("All 24 Major and Minor Keys")
+print("=" * 55)
+print()
+
+for key in Key.all_keys():
+    sig = key.signature
+    acc = ", ".join(sig["accidentals"]) if sig["accidentals"] else "none"
+    rel = key.relative
+    print(
+        f"  {str(key):12s}  "
+        f"{sig['sharps']}# {sig['flats']}b  "
+        f"({acc:15s})  "
+        f"rel: {rel}"
+    )

examples/key_explorer.py

@@ -0,0 +1,58 @@
+"""Explore a key — its chords, progressions, and relationships."""
+
+from pytheory import Key
+
+def explore_key(tonic, mode="major"):
+    key = Key(tonic, mode)
+    sig = key.signature
+    acc = ", ".join(sig["accidentals"]) or "none"
+
+    print(f"{'=' * 60}")
+    print(f"  {key}")
+    print(f"{'=' * 60}")
+    print()
+    print(f"  Scale:       {' '.join(key.note_names)}")
+    print(f"  Signature:   {sig['sharps']} sharps, {sig['flats']} flats ({acc})")
+    print(f"  Relative:    {key.relative}")
+    print(f"  Parallel:    {key.parallel}")
+    print()
+
+    # Diatonic triads
+    print("  Diatonic Triads:")
+    for chord in key.scale.harmonize():
+        numeral = chord.analyze(tonic, mode) or "?"
+        print(f"    {numeral:6s}  {chord.identify()}")
+    print()
+
+    # Seventh chords
+    print("  Seventh Chords:")
+    for name in key.seventh_chords:
+        print(f"    {name}")
+    print()
+
+    # Common progressions
+    print("  Common Progressions:")
+    progressions = {
+        "Pop":     ("I", "V", "vi", "IV"),
+        "Blues":   ("I", "IV", "V"),
+        "50s":     ("I", "vi", "IV", "V"),
+        "Jazz":    ("ii", "V", "I"),
+    }
+    for label, numerals in progressions.items():
+        chords = key.progression(*numerals)
+        names = [c.identify() for c in chords]
+        print(f"    {label:8s}  {' → '.join(numerals):20s}  {' → '.join(names)}")
+    print()
+
+    # Borrowed chords
+    borrowed = key.borrowed_chords
+    if borrowed:
+        print(f"  Borrowed from {key.parallel}:")
+        for name in borrowed[:4]:
+            print(f"    {name}")
+        print()
+
+
+# Explore several keys
+for tonic, mode in [("C", "major"), ("G", "major"), ("A", "minor"), ("E", "major")]:
+    explore_key(tonic, mode)

examples/midi_converter.py

@@ -0,0 +1,35 @@
+"""Convert between MIDI note numbers, frequencies, and note names."""
+
+from pytheory import Tone
+
+print("MIDI ↔ Note ↔ Frequency Reference")
+print("=" * 50)
+print()
+print(f"{'MIDI':>5s}  {'Note':>5s}  {'Freq (Hz)':>10s}  {'Octave':>6s}")
+print(f"{'─' * 5}  {'─' * 5}  {'─' * 10}  {'─' * 6}")
+
+# Show all notes from C2 to C7
+for midi in range(36, 97):
+    tone = Tone.from_midi(midi)
+    freq = tone.frequency
+    print(f"{midi:>5d}  {tone.full_name:>5s}  {freq:>10.2f}  {tone.octave:>6d}")
+
+# Useful reference points
+print()
+print("Key Reference Points:")
+print(f"  Lowest piano note:   A0  = MIDI {Tone.from_string('A0', system='western').midi}")
+print(f"  Middle C:            C4  = MIDI {Tone.from_string('C4', system='western').midi}")
+print(f"  Concert A:           A4  = MIDI {Tone.from_string('A4', system='western').midi}")
+print(f"  Highest piano note:  C8  = MIDI {Tone.from_string('C8', system='western').midi}")
+
+# Round-trip demo
+print()
+print("Round-trip conversions:")
+for start in ["C4", "A4", "F#3", "Bb5"]:
+    tone = Tone.from_string(start, system="western")
+    midi = tone.midi
+    freq = tone.frequency
+    from_midi = Tone.from_midi(midi)
+    from_freq = Tone.from_frequency(freq)
+    print(f"  {start:4s} → MIDI {midi} → {from_midi.full_name:4s} | "
+          f"{start:4s} → {freq:.2f} Hz → {from_freq.full_name}")

examples/overtone_series.py

@@ -0,0 +1,68 @@
+"""Explore the overtone series — nature's chord."""
+
+from pytheory import Tone, Chord
+
+a4 = Tone.from_string("A4", system="western")
+
+print("The Overtone Series")
+print("=" * 65)
+print()
+print("When you play a note, you're actually hearing many frequencies")
+print("at once. The fundamental plus its integer multiples:")
+print()
+print(f"{'Harmonic':>9s}  {'Frequency':>10s}  {'Nearest Note':>13s}  {'Interval from Root'}")
+print(f"{'─' * 9}  {'─' * 10}  {'─' * 13}  {'─' * 25}")
+
+overtones = a4.overtones(16)
+
+for i, hz in enumerate(overtones, 1):
+    nearest = Tone.from_frequency(hz)
+    if i == 1:
+        interval = "Fundamental"
+    else:
+        interval = a4.interval_to(nearest)
+    print(f"{i:>9d}  {hz:>10.1f}  {nearest.full_name:>13s}  {interval}")
+
+# ── Why Chords Sound Good ───────────────────────────────────────────────
+
+print()
+print("Why the Major Triad Sounds 'Natural'")
+print("=" * 65)
+print()
+print("The first 6 harmonics contain: root, octave, 5th, 2nd octave, 3rd, 5th")
+print("That's a major triad! The major chord is literally embedded in physics.")
+print()
+
+c4 = Tone.from_string("C4", system="western")
+harmonics = c4.overtones(6)
+harmonic_names = [Tone.from_frequency(hz).name for hz in harmonics]
+unique = []
+for n in harmonic_names:
+    if n not in unique:
+        unique.append(n)
+print(f"  First 6 harmonics of C: {', '.join(harmonic_names)}")
+print(f"  Unique pitch classes:   {', '.join(unique)}")
+print(f"  C major triad:          C, E, G")
+print()
+
+# ── Shared Overtones = Consonance ───────────────────────────────────────
+
+print("Shared Overtones Between Intervals")
+print("=" * 65)
+print()
+print("The more overtones two notes share, the more consonant they sound.")
+print()
+
+root = Tone.from_string("C4", system="western")
+root_overtones = set(round(h, 1) for h in root.overtones(12))
+
+for semitones, label in [(7, "Perfect 5th (C→G)"),
+                          (4, "Major 3rd (C→E)"),
+                          (5, "Perfect 4th (C→F)"),
+                          (3, "Minor 3rd (C→Eb)"),
+                          (6, "Tritone (C→F#)"),
+                          (1, "Minor 2nd (C→C#)")]:
+    other = root + semitones
+    other_overtones = set(round(h, 1) for h in other.overtones(12))
+    shared = root_overtones & other_overtones
+    print(f"  {label:25s}  {len(shared):2d} shared overtones (of first 12)")

examples/progression_writer.py

@@ -0,0 +1,81 @@
+"""Build and analyze chord progressions in any key."""
+
+from pytheory import Key, Chord
+
+def show_progression(key, numerals, label=""):
+    chords = key.progression(*numerals)
+    if label:
+        print(f"  {label}")
+    print(f"    Key: {key}")
+    print(f"    Progression: {' – '.join(numerals)}")
+    print()
+    for numeral, chord in zip(numerals, chords):
+        t = chord.tension
+        print(
+            f"      {numeral:6s}  {chord.identify():20s}  "
+            f"tension={t['score']:.2f}  "
+            f"{'*** DOMINANT ***' if t['has_dominant_function'] else ''}"
+        )
+    print()
+
+
+# ── Famous Progressions ─────────────────────────────────────────────────
+
+print("Famous Chord Progressions")
+print("=" * 65)
+print()
+
+key_c = Key("C", "major")
+
+show_progression(key_c, ("I", "V", "vi", "IV"),
+    "The Pop Progression (Let It Be, No Woman No Cry, Someone Like You)")
+
+show_progression(key_c, ("I", "vi", "IV", "V"),
+    "The 50s Progression (Stand By Me, Every Breath You Take)")
+
+show_progression(key_c, ("ii", "V", "I"),
+    "Jazz ii–V–I (the backbone of jazz harmony)")
+
+show_progression(key_c, ("I", "IV", "V", "I"),
+    "The Three-Chord Trick (blues, rock, country)")
+
+# ── Same Progression in Different Keys ──────────────────────────────────
+
+print("─" * 65)
+print()
+print("I – V – vi – IV in every key:")
+print()
+
+for tonic in ["C", "G", "D", "A", "E", "F", "Bb", "Eb"]:
+    key = Key(tonic, "major")
+    chords = key.progression("I", "V", "vi", "IV")
+    names = [c.identify() for c in chords]
+    print(f"  {tonic} major:  {' → '.join(names)}")
+
+# ── Nashville Number System ─────────────────────────────────────────────
+
+print()
+print("─" * 65)
+print()
+print("Nashville Number System:")
+print("  (Same thing as Roman numerals, but with integers)")
+print()
+
+key_g = Key("G", "major")
+chords = key_g.nashville(1, 5, 6, 4)
+names = [c.identify() for c in chords]
+print(f"  G major: 1 – 5 – 6 – 4  →  {' → '.join(names)}")
+
+# ── Random Progression Generator ────────────────────────────────────────
+
+print()
+print("─" * 65)
+print()
+print("Random 8-bar progressions:")
+print()
+
+for _ in range(3):
+    key = Key("C", "major")
+    chords = key.random_progression(8)
+    names = [c.identify().split()[0] for c in chords]  # Just root names
+    print(f"  | {'  | '.join(names)}  |")

examples/song.py

@@ -1,78 +1,216 @@
-from time import sleep
+"""Play melodies and chord progressions with PyTheory.
 
-from pytheory import TonedScale, Tone, CHARTS, play
+Requires PortAudio: brew install portaudio (macOS)
+"""
+
+from pytheory import Tone, Chord, Key, TonedScale, play, Synth
+
+# ── Helpers ─────────────────────────────────────────────────────────────
+
+BPM = 180
+BEAT = 60_000 // BPM  # ms per beat
 
 
-# Add this constant at the top of the file, after the imports
-EIGHTH_NOTE = 0.25
-QUARTER_NOTE = 0.5
-
-# Add scale definition after the constants
-C_MAJOR = TonedScale(tonic="C4")
+def play_melody(notes, synth=Synth.SINE):
+    """Play a sequence of (note_string, beats) tuples."""
+    try:
+        for note, beats in notes:
+            if note == "REST":
+                import time
+                time.sleep(beats * BEAT / 1000)
+            else:
+                tone = Tone.from_string(note, system="western")
+                play(tone, synth=synth, t=int(beats * BEAT))
+    except KeyboardInterrupt:
+        print("\n  Stopped.")
 
 
-def play_note(note, t=0.1):
-    # Convert scale degree (1-7) to note name (0-based index)
-    scale_notes = ["C4", "D4", "E4", "F4", "G4", "A4", "B4"]
-    note_name = scale_notes[note - 1]  # Subtract 1 because scale degrees are 1-based
-    tone = Tone(note_name)
-    play(tone, t=t * 1_000)
-    sleep(t)
+def play_progression(chords, beats_each=2, synth=Synth.SINE):
+    """Play a list of Chord objects."""
+    try:
+        for chord in chords:
+            name = chord.identify() or "?"
+            tones = " ".join(t.full_name for t in chord.tones)
+            print(f"  {name:20s}  {tones}")
+            play(chord, synth=synth, t=int(beats_each * BEAT))
+    except KeyboardInterrupt:
+        print("\n  Stopped.")
 
 
-# Twinkle Twinkle Little Star in C major
-# C C G G A A G (first line)
-# F F E E D D C (second line)
-# G G F F E E D (third line)
-# G G F F E E D (fourth line)
-# C C G G A A G (fifth line)
-# F F E E D D C (sixth line)
+# ── Songs ───────────────────────────────────────────────────────────────
 
+def twinkle_twinkle():
+    """Twinkle Twinkle Little Star — C major."""
+    print("Twinkle Twinkle Little Star")
+    print("=" * 40)
 
-def play_twinkle():
-    # Define the patterns using scale degrees instead of note names
-    line1 = [
-        (1, EIGHTH_NOTE),  # C4
-        (1, EIGHTH_NOTE),  # C4
-        (5, EIGHTH_NOTE),  # G4
-        (5, EIGHTH_NOTE),  # G4
-        (6, EIGHTH_NOTE),  # A4
-        (6, EIGHTH_NOTE),  # A4
-        (5, QUARTER_NOTE),  # G4
-    ]
-    line2 = [
-        (4, EIGHTH_NOTE),  # F4
-        (4, EIGHTH_NOTE),  # F4
-        (3, EIGHTH_NOTE),  # E4
-        (3, EIGHTH_NOTE),  # E4
-        (2, EIGHTH_NOTE),  # D4
-        (2, EIGHTH_NOTE),  # D4
-        (1, QUARTER_NOTE),  # C4
-    ]
-    line3 = [
-        (5, EIGHTH_NOTE),  # G4
-        (5, EIGHTH_NOTE),  # G4
-        (4, EIGHTH_NOTE),  # F4
-        (4, EIGHTH_NOTE),  # F4
-        (3, EIGHTH_NOTE),  # E4
-        (3, EIGHTH_NOTE),  # E4
-        (2, QUARTER_NOTE),  # D4
+    melody = [
+        # Twinkle twinkle little star
+        ("C4", 1), ("C4", 1), ("G4", 1), ("G4", 1),
+        ("A4", 1), ("A4", 1), ("G4", 2),
+        # How I wonder what you are
+        ("F4", 1), ("F4", 1), ("E4", 1), ("E4", 1),
+        ("D4", 1), ("D4", 1), ("C4", 2),
+        # Up above the world so high
+        ("G4", 1), ("G4", 1), ("F4", 1), ("F4", 1),
+        ("E4", 1), ("E4", 1), ("D4", 2),
+        # Like a diamond in the sky
+        ("G4", 1), ("G4", 1), ("F4", 1), ("F4", 1),
+        ("E4", 1), ("E4", 1), ("D4", 2),
+        # Twinkle twinkle little star
+        ("C4", 1), ("C4", 1), ("G4", 1), ("G4", 1),
+        ("A4", 1), ("A4", 1), ("G4", 2),
+        # How I wonder what you are
+        ("F4", 1), ("F4", 1), ("E4", 1), ("E4", 1),
+        ("D4", 1), ("D4", 1), ("C4", 2),
     ]
 
-    # Construct the full melody using the patterns
-    melody = (
-        line1  # Twinkle twinkle little star
-        + line2  # How I wonder what you are
-        + line3  # Up above the world so high
-        + line3  # Like a diamond in the sky
-        + line1  # Twinkle twinkle little star
-        + line2  # How I wonder what you are
-    )
+    play_melody(melody)
 
-    print("Playing Twinkle Twinkle Little Star...")
-    for note, duration in melody:
-        play_note(note, duration)
 
+def ode_to_joy():
+    """Ode to Joy — Beethoven's 9th Symphony, D major."""
+    print("Ode to Joy (Beethoven)")
+    print("=" * 40)
+
+    melody = [
+        # Main theme
+        ("F#4", 1), ("F#4", 1), ("G4", 1), ("A4", 1),
+        ("A4", 1), ("G4", 1), ("F#4", 1), ("E4", 1),
+        ("D4", 1), ("D4", 1), ("E4", 1), ("F#4", 1),
+        ("F#4", 1.5), ("E4", 0.5), ("E4", 2),
+        # Repeat with variation
+        ("F#4", 1), ("F#4", 1), ("G4", 1), ("A4", 1),
+        ("A4", 1), ("G4", 1), ("F#4", 1), ("E4", 1),
+        ("D4", 1), ("D4", 1), ("E4", 1), ("F#4", 1),
+        ("E4", 1.5), ("D4", 0.5), ("D4", 2),
+    ]
+
+    play_melody(melody)
+
+
+def happy_birthday():
+    """Happy Birthday — G major."""
+    print("Happy Birthday")
+    print("=" * 40)
+
+    melody = [
+        # Happy birthday to you
+        ("G4", 0.75), ("G4", 0.25), ("A4", 1), ("G4", 1),
+        ("C5", 1), ("B4", 2),
+        # Happy birthday to you
+        ("G4", 0.75), ("G4", 0.25), ("A4", 1), ("G4", 1),
+        ("D5", 1), ("C5", 2),
+        # Happy birthday dear [name]
+        ("G4", 0.75), ("G4", 0.25), ("G5", 1), ("E5", 1),
+        ("C5", 1), ("B4", 1), ("A4", 2),
+        # Happy birthday to you
+        ("F5", 0.75), ("F5", 0.25), ("E5", 1), ("C5", 1),
+        ("D5", 1), ("C5", 2),
+    ]
+
+    play_melody(melody)
+
+
+def fur_elise():
+    """Fur Elise — opening bars (A minor)."""
+    print("Fur Elise (opening)")
+    print("=" * 40)
+
+    melody = [
+        ("E5", 0.5), ("D#5", 0.5), ("E5", 0.5), ("D#5", 0.5),
+        ("E5", 0.5), ("B4", 0.5), ("D5", 0.5), ("C5", 0.5),
+        ("A4", 1), ("REST", 0.5),
+        ("C4", 0.5), ("E4", 0.5), ("A4", 0.5),
+        ("B4", 1), ("REST", 0.5),
+        ("E4", 0.5), ("G#4", 0.5), ("B4", 0.5),
+        ("C5", 1), ("REST", 0.5),
+        ("E4", 0.5), ("E5", 0.5), ("D#5", 0.5),
+        ("E5", 0.5), ("D#5", 0.5), ("E5", 0.5), ("B4", 0.5),
+        ("D5", 0.5), ("C5", 0.5),
+        ("A4", 1),
+    ]
+
+    play_melody(melody)
+
+
+def pop_progression():
+    """The I–V–vi–IV pop progression in C major."""
+    print("Pop Progression (I-V-vi-IV in C)")
+    print("=" * 40)
+    print()
+
+    key = Key("C", "major")
+    chords = key.progression("I", "V", "vi", "IV")
+
+    # Play it twice
+    play_progression(chords * 2)
+
+
+def blues_in_a():
+    """12-bar blues in A."""
+    print("12-Bar Blues in A")
+    print("=" * 40)
+    print()
+
+    key = Key("A", "major")
+    I = key.triad(0)
+    IV = key.triad(3)
+    V = key.triad(4)
+
+    bars = [I, I, I, I, IV, IV, I, I, V, IV, I, V]
+
+    play_progression(bars, beats_each=1.5)
+
+
+def jazz_ii_v_i():
+    """Jazz ii–V–I turnaround through several keys."""
+    print("Jazz ii-V-I Turnaround")
+    print("=" * 40)
+    print()
+
+    for tonic in ["C", "F", "Bb", "Eb"]:
+        key = Key(tonic, "major")
+        chords = key.progression("ii", "V", "I")
+        print(f"  Key of {tonic}:")
+        play_progression(chords, beats_each=1.5)
+        print()
+
+
+# ── Main ────────────────────────────────────────────────────────────────
+
+SONGS = {
+    "1": ("Twinkle Twinkle Little Star", twinkle_twinkle),
+    "2": ("Ode to Joy", ode_to_joy),
+    "3": ("Happy Birthday", happy_birthday),
+    "4": ("Fur Elise (opening)", fur_elise),
+    "5": ("Pop Progression (I-V-vi-IV)", pop_progression),
+    "6": ("12-Bar Blues in A", blues_in_a),
+    "7": ("Jazz ii-V-I Turnaround", jazz_ii_v_i),
+}
 
 if __name__ == "__main__":
-    play_twinkle()
+    try:
+        print("PyTheory Song Player")
+        print("=" * 40)
+        print()
+
+        for key, (name, _) in SONGS.items():
+            print(f"  {key}. {name}")
+
+        print()
+        choice = input("Pick a song (1-7, or 'all'): ").strip()
+
+        if choice == "all":
+            for _, (_, fn) in SONGS.items():
+                fn()
+                print()
+        elif choice in SONGS:
+            SONGS[choice][1]()
+        else:
+            print("Playing all melodies...")
+            for _, (_, fn) in SONGS.items():
+                fn()
+                print()
+    except KeyboardInterrupt:
+        print("\n\nBye!")

examples/temperament_comparison.py

@@ -0,0 +1,49 @@
+"""Compare equal, Pythagorean, and meantone temperaments."""
+
+import math
+from pytheory import Tone
+
+a4 = Tone.from_string("A4", system="western")
+
+print("Temperament Comparison")
+print("=" * 75)
+print()
+print(f"{'Note':>5s}  {'Equal (Hz)':>12s}  {'Pythag (Hz)':>12s}  {'Meantone (Hz)':>14s}  {'P diff':>8s}  {'M diff':>8s}")
+print(f"{'─' * 5}  {'─' * 12}  {'─' * 12}  {'─' * 14}  {'─' * 8}  {'─' * 8}")
+
+for semitones in range(13):
+    tone = a4 + semitones
+
+    equal = tone.pitch(temperament="equal")
+    pyth = tone.pitch(temperament="pythagorean")
+    mean = tone.pitch(temperament="meantone")
+
+    # Difference in cents (1 cent = 1/100 of a semitone)
+    pyth_cents = 1200 * math.log2(pyth / equal) if pyth > 0 else 0
+    mean_cents = 1200 * math.log2(mean / equal) if mean > 0 else 0
+
+    print(
+        f"{tone.name:>5s}  {equal:>12.3f}  {pyth:>12.3f}  {mean:>14.3f}"
+        f"  {pyth_cents:>+7.1f}¢  {mean_cents:>+7.1f}¢"
+    )
+
+print()
+print("Key intervals to listen for:")
+print()
+
+intervals = [
+    (4, "Major 3rd", "Meantone is pure (5:4), equal is sharp, Pythagorean sharper still"),
+    (7, "Perfect 5th", "Pythagorean is pure (3:2), equal is slightly flat, meantone flatter"),
+    (6, "Tritone", "The 'devil's interval' — all three temperaments handle it differently"),
+]
+
+for semitones, name, note in intervals:
+    tone = a4 + semitones
+    equal = tone.pitch(temperament="equal")
+    pyth = tone.pitch(temperament="pythagorean")
+    mean = tone.pitch(temperament="meantone")
+
+    print(f"  {name} ({a4.name}→{tone.name}):")
+    print(f"    Equal: {equal:.3f} Hz  |  Pythagorean: {pyth:.3f} Hz  |  Meantone: {mean:.3f} Hz")
+    print(f"    {note}")
+    print()

examples/world_scales.py

@@ -0,0 +1,68 @@
+"""Explore scales from six musical traditions around the world."""
+
+from pytheory import TonedScale
+
+systems = [
+    ("western", "C4", [
+        ("major", "The foundation of Western tonal music"),
+        ("minor", "Natural minor — dark and introspective"),
+        ("harmonic minor", "Raised 7th — classical, Middle Eastern flavor"),
+        ("dorian", "Jazz, funk, soul (So What, Scarborough Fair)"),
+        ("mixolydian", "Blues, rock (Norwegian Wood, Sweet Home Alabama)"),
+        ("phrygian", "Flamenco, metal (White Rabbit)"),
+        ("lydian", "Dreamy, floating (The Simpsons theme)"),
+    ]),
+    ("indian", "Sa4", [
+        ("bilawal", "Equivalent to Western major scale"),
+        ("bhairav", "Morning raga — devotional, meditative"),
+        ("kafi", "Equivalent to Dorian mode — romantic, earthy"),
+        ("bhairavi", "Equivalent to Phrygian — melancholic, devotional"),
+        ("kalyan", "Equivalent to Lydian — serene, uplifting"),
+    ]),
+    ("arabic", "Do4", [
+        ("ajam", "Equivalent to Western major scale"),
+        ("hijaz", "The quintessential 'Middle Eastern' sound"),
+        ("bayati", "Contemplative, spiritual — most common maqam"),
+        ("rast", "Bright, festive — the 'mother' of maqamat"),
+        ("nahawand", "Equivalent to Western minor — melancholic"),
+    ]),
+    ("japanese", "C4", [
+        ("hirajoshi", "Haunting pentatonic — koto music"),
+        ("in", "Dark pentatonic — court music, Buddhist chant"),
+        ("yo", "Bright pentatonic — folk songs, festival music"),
+        ("iwato", "Sparse, mysterious — zen atmosphere"),
+        ("kumoi", "Gentle pentatonic — lyrical, nostalgic"),
+        ("ritsu", "Elegant heptatonic — gagaku court music"),
+    ]),
+    ("blues", "C4", [
+        ("blues", "The 6-note blues scale with the 'blue note'"),
+        ("minor pentatonic", "The backbone of rock guitar solos"),
+        ("major pentatonic", "Bright, open — country, folk, pop"),
+    ]),
+    ("gamelan", "nem4", [
+        ("slendro", "5-note near-equal division — metallic, shimmering"),
+        ("pelog", "7-note unequal — mysterious, otherworldly"),
+        ("pelog nem", "Pelog mode on nem — the most common mode"),
+        ("pelog barang", "Pelog mode on barang — bright, festive"),
+    ]),
+]
+
+for system_name, tonic, scales in systems:
+    print(f"{'═' * 65}")
+    print(f"  {system_name.upper()}")
+    print(f"{'═' * 65}")
+
+    ts = TonedScale(tonic=tonic, system=system_name)
+
+    for scale_name, description in scales:
+        try:
+            scale = ts[scale_name]
+            notes = " ".join(scale.note_names)
+            print(f"  {scale_name:20s}  {notes}")
+            print(f"  {'':20s}  {description}")
+            print()
+        except (KeyError, IndexError, ValueError):
+            print(f"  {scale_name:20s}  (not available)")
+            print()
+
+print(f"{'═' * 65}")

pyproject.toml

@@ -1,6 +1,6 @@
 [project]
 name = "pytheory"
-version = "0.4.1"
+version = "0.7.0"
 description = "Music Theory for Humans"
 readme = "README.md"
 license = "MIT"

pytheory/__init__.py

@@ -1,17 +1,18 @@
 """PyTheory: Music Theory for Humans."""
 
-__version__ = "0.4.1"
+__version__ = "0.7.0"
 
 from .tones import Tone, Interval
 from .systems import System, SYSTEMS
 from .scales import Scale, TonedScale, Key, PROGRESSIONS
 from .chords import Chord, Fretboard, analyze_progression
-from .charts import CHARTS, charts_for_fretboard
+from .charts import CHARTS, Fingering, charts_for_fretboard
 
 try:
-    from .play import play, Synth
+    from .play import play, save, Synth
 except OSError:
     play = None
+    save = None
     Synth = None
 
 # Aliases for discoverability.
@@ -19,7 +20,7 @@ Note = Tone
 
 __all__ = [
     "Tone", "Note", "Interval", "Scale", "TonedScale", "Key",
-    "PROGRESSIONS", "Chord", "Fretboard", "analyze_progression",
+    "PROGRESSIONS", "Chord", "Fretboard", "Fingering", "analyze_progression",
     "System", "SYSTEMS", "CHARTS", "charts_for_fretboard",
-    "play", "Synth",
+    "play", "save", "Synth",
 ]

pytheory/_statics.py

@@ -175,20 +175,6 @@ SCALES = {
                 # "melodic minor": {"minor": True, "melodic": True, "hemitonic": True},
             },
         ],
-        # TODO: understand this
-        # "hexatonic": (
-        #     6,
-        #     {
-        #         # name, arguments to scale generator.
-        #         "wholetone": {},
-        #         "augmented": {},
-        #         "prometheus": {},
-        #         "blues": {},
-        #     },
-        # ),
-        # "pentatonic": (5, {}),
-        # "tetratonic": (4, {}),
-        # "monotonic": (1, {"monotonic": {"hemitonic": False}}),
     }
 }
 

pytheory/charts.py

@@ -1,4 +1,5 @@
 import itertools
+from typing import Optional
 
 from .systems import SYSTEMS
 from .tones import Tone
@@ -6,6 +7,106 @@ from .tones import Tone
 QUALITIES = ("", "maj", "m", "5", "7", "9", "dim", "m6", "m7", "m9", "maj7", "maj9")
 MAX_FRET = 7
 
+
+class Fingering:
+    """A chord fingering labeled with string names.
+
+    Provides both index and named access to fret positions, making it
+    clear which string each position corresponds to.
+
+    Example::
+
+        >>> f = Fingering(positions=(0, 3, 2, 0, 1, 0),
+        ...               string_names=('E', 'A', 'D', 'G', 'B', 'e'))
+        >>> f
+        Fingering(E=0, A=3, D=2, G=0, B=1, e=0)
+        >>> f['A']
+        3
+        >>> f[1]
+        3
+    """
+
+    def __init__(self, positions: tuple, string_names: tuple[str, ...], *, fretboard=None) -> None:
+        self.positions = tuple(positions)
+        self._fretboard = fretboard
+        # Disambiguate duplicate names: for standard guitar tuning
+        # (high-to-low), the first occurrence of a duplicate becomes
+        # lowercase (e.g. high E → 'e') while the last keeps uppercase.
+        from collections import Counter
+        name_counts = Counter(string_names)
+        seen: dict[str, int] = {}
+        unique_names: list[str] = []
+        for name in string_names:
+            seen[name] = seen.get(name, 0) + 1
+            if name_counts[name] > 1 and seen[name] < name_counts[name]:
+                unique_names.append(name.lower())
+            else:
+                unique_names.append(name)
+
+        self.string_names = tuple(unique_names)
+        self._map = dict(zip(self.string_names, self.positions))
+
+    def __repr__(self) -> str:
+        pairs = ", ".join(
+            f"{name}={'x' if pos is None else pos}"
+            for name, pos in zip(self.string_names, self.positions)
+        )
+        return f"Fingering({pairs})"
+
+    def __getitem__(self, key):
+        if isinstance(key, int):
+            return self.positions[key]
+        return self._map[key]
+
+    def __iter__(self):
+        return iter(self.positions)
+
+    def __len__(self):
+        return len(self.positions)
+
+    def __eq__(self, other):
+        if isinstance(other, Fingering):
+            return self.positions == other.positions and self.string_names == other.string_names
+        if isinstance(other, tuple):
+            return self.positions == other
+        return NotImplemented
+
+    @property
+    def tones(self):
+        """Return the sounding tones for this fingering.
+
+        Requires that the Fingering was created with a fretboard reference.
+        Muted strings (``None``) are excluded.
+        """
+        if self._fretboard is None:
+            raise ValueError("Cannot resolve tones without a fretboard reference.")
+        tones = []
+        for pos, tone in zip(self.positions, self._fretboard.tones):
+            if pos is not None:
+                tones.append(tone.add(pos))
+        return tones
+
+    def to_chord(self, fretboard=None) -> "Chord":
+        """Apply this fingering to a fretboard, returning a Chord.
+
+        Strings with ``None`` positions (muted) are excluded.
+        If no fretboard is given, uses the one stored at creation time.
+        """
+        from .chords import Chord
+
+        fb = fretboard or self._fretboard
+        if fb is None:
+            raise ValueError("No fretboard provided.")
+        tones = []
+        for pos, tone in zip(self.positions, fb.tones):
+            if pos is not None:
+                tones.append(tone.add(pos))
+        return Chord(tones=tones)
+
+    def identify(self) -> Optional[str]:
+        """Identify the chord name from this fingering."""
+        return self.to_chord().identify()
+
 CHARTS = {}
 CHARTS["western"] = []
 
@@ -148,11 +249,12 @@ class NamedChord:
                 if fingering_score(possible_fingering) == max_score:
                     yield possible_fingering
 
+        string_names = tuple(t.name for t in fretboard.tones)
         best_fingerings = tuple([g for g in gen()])
         if not multiple:
-            return self.fix_fingering(best_fingerings[0])
+            return Fingering(self.fix_fingering(best_fingerings[0]), string_names, fretboard=fretboard)
         else:
-            return tuple([self.fix_fingering(f) for f in best_fingerings])
+            return tuple([Fingering(self.fix_fingering(f), string_names, fretboard=fretboard) for f in best_fingerings])
 
     def tab(self, *, fretboard):
         """Render this chord as ASCII guitar tablature.

pytheory/chords.py

@@ -680,8 +680,8 @@ class Chord:
         """
         return Chord(tones=[t for t in self.tones if t.name != tone_name])
 
-    def fingering(self, *positions: int) -> Chord:
-        """Apply fret positions to each tone, returning a new Chord.
+    def fingering(self, *positions: int) -> "Fingering":
+        """Apply fret positions to each tone, returning a Fingering.
 
         Each position value is added (in semitones) to the corresponding
         tone. The number of positions must match the number of tones.
@@ -690,22 +690,21 @@ class Chord:
             *positions: One integer per tone indicating the fret offset.
 
         Returns:
-            A new :class:`Chord` with each tone shifted by its position.
+            A :class:`Fingering` labeled with tone names.
 
         Raises:
             ValueError: If the number of positions doesn't match the
                 number of tones.
         """
+        from .charts import Fingering
+
         if not len(positions) == len(self.tones):
             raise ValueError(
                 "The number of positions must match the number of tones (strings)."
             )
 
-        tones = []
-        for i, tone in enumerate(self.tones):
-            tones.append(tone.add(positions[i]))
-
-        return Chord(tones=tones)
+        string_names = tuple(t.name for t in self.tones)
+        return Fingering(positions, string_names)
 
 
 class Fretboard:
@@ -1252,8 +1251,27 @@ class Fretboard:
 
         return "\n".join(lines)
 
-    def fingering(self, *positions: int) -> Chord:
-        """Apply fret positions to each string, returning a Chord.
+    def chord(self, name: str, *, system: str = "western") -> "Fingering":
+        """Look up a chord by name and return its best fingering.
+
+        Args:
+            name: Chord name like ``"G"``, ``"Am7"``, ``"Bb"``, ``"Dm"``.
+            system: Tonal system to use (default ``"western"``).
+
+        Returns:
+            A :class:`Fingering` for that chord on this fretboard.
+
+        Example::
+
+            >>> fb = Fretboard.guitar()
+            >>> fb.chord("G")
+            Fingering(e=3, B=0, G=0, D=0, A=2, E=3)
+        """
+        from .charts import CHARTS
+        return CHARTS[system][name].fingering(fretboard=self)
+
+    def fingering(self, *positions: int) -> "Fingering":
+        """Apply fret positions to each string, returning a Fingering.
 
         Each position value is added (in semitones) to the corresponding
         open-string tone. The number of positions must match the number
@@ -1263,22 +1281,22 @@ class Fretboard:
             *positions: One integer per string indicating the fret number.
 
         Returns:
-            A :class:`Chord` with each tone shifted by its fret position.
+            A :class:`Fingering` labeled with string names. Call
+            ``.to_chord(fretboard)`` or use the resulting chord directly.
 
         Raises:
             ValueError: If the number of positions doesn't match the
                 number of strings.
         """
+        from .charts import Fingering
+
         if not len(positions) == len(self.tones):
             raise ValueError(
                 "The number of positions must match the number of tones (strings)."
             )
 
-        tones = []
-        for i, tone in enumerate(self.tones):
-            tones.append(tone.add(positions[i]))
-
-        return Chord(tones=tones)
+        string_names = tuple(t.name for t in self.tones)
+        return Fingering(positions, string_names, fretboard=self)
 
 
 def analyze_progression(chords: list[Chord], key: str = "C", mode: str = "major") -> list[str | None]:

pytheory/cli.py

@@ -91,6 +91,42 @@ def cmd_progression(args):
         print(f"    {numeral:6s}  {chord}")
 
 
+def cmd_play(args):
+    from .tones import Tone
+    from .chords import Chord
+    from .play import play, Synth
+
+    synth_map = {"sine": Synth.SINE, "saw": Synth.SAW, "triangle": Synth.TRIANGLE}
+    synth = synth_map[args.synth]
+    duration = args.duration
+
+    # Try chord name first (e.g. "Am", "Cmaj7"), then fall back to individual notes.
+    if len(args.notes) == 1:
+        note = args.notes[0]
+        # Try as chord name first (Am, G7, Cmaj7, etc.)
+        try:
+            target = Chord.from_name(note)
+            name = target.identify() or note
+            label = f"{name} ({' '.join(t.full_name for t in target.tones)})"
+        except (ValueError, KeyError):
+            # Fall back to single tone
+            target = Tone.from_string(
+                note if any(c.isdigit() for c in note) else f"{note}4",
+                system="western")
+            label = target.full_name
+    else:
+        tones = [Tone.from_string(n if any(c.isdigit() for c in n) else f"{n}4",
+                                  system="western") for n in args.notes]
+        target = Chord(tones=tones)
+        name = target.identify() or "Custom"
+        label = f"{name} ({' '.join(t.full_name for t in tones)})"
+
+    print(f"  Playing: {label}")
+    print(f"  Synth:   {args.synth}")
+    print(f"  Duration: {duration} ms")
+    play(target, temperament=args.temperament, synth=synth, t=duration)
+
+
 def cmd_detect(args):
     from .scales import Key
     key = Key.detect(*args.notes)
@@ -141,6 +177,18 @@ def main():
     p.add_argument("mode", help="Mode (e.g. major, minor)")
     p.add_argument("numerals", nargs="+", help="Roman numerals (e.g. I V vi IV)")
 
+    # play
+    p = sub.add_parser("play", help="Play notes or chords (e.g. pytheory play C E G)")
+    p.add_argument("notes", nargs="+", help="Note names, with optional octave (e.g. C4, A#3, or just C E G)")
+    p.add_argument("--synth", "-s", default="sine",
+                   choices=["sine", "saw", "triangle"],
+                   help="Waveform (default: sine)")
+    p.add_argument("--duration", "-d", type=int, default=1000,
+                   help="Duration in milliseconds (default: 1000)")
+    p.add_argument("--temperament", "-t", default="equal",
+                   choices=["equal", "pythagorean", "meantone"],
+                   help="Tuning temperament (default: equal)")
+
     # detect
     p = sub.add_parser("detect", help="Detect key from notes (e.g. pytheory detect C E G)")
     p.add_argument("notes", nargs="+", help="Note names")
@@ -157,6 +205,7 @@ def main():
         "key": cmd_key,
         "fingering": cmd_fingering,
         "progression": cmd_progression,
+        "play": cmd_play,
         "detect": cmd_detect,
     }
     commands[args.command](args)

pytheory/play.py

@@ -5,8 +5,8 @@ import sounddevice as sd
 
 from .tones import Tone
 
-SAMPLE_RATE = 44_100
-SAMPLE_PEAK = 4_096
+SAMPLE_RATE = 44_100   # CD-quality sample rate (Hz)
+SAMPLE_PEAK = 4_096    # Peak amplitude for 16-bit integer samples
 
 
 def sine_wave(hz, peak=SAMPLE_PEAK, n_samples=SAMPLE_RATE):
@@ -20,41 +20,33 @@ def sine_wave(hz, peak=SAMPLE_PEAK, n_samples=SAMPLE_RATE):
     return numpy.resize(onecycle, (n_samples,)).astype(numpy.int16)
 
 
-def sawtooth_wave(hz, peak=SAMPLE_PEAK, rising_ramp_width=1, n_samples=SAMPLE_RATE):
-    """Compute N samples of a sine wave with given frequency and peak amplitude.
+def sawtooth_wave(hz, peak=SAMPLE_PEAK, n_samples=SAMPLE_RATE):
+    """Compute N samples of a sawtooth wave with given frequency and peak amplitude.
     Defaults to one second.
-    rising_ramp_width is the percentage of the ramp spend rising:
-    .5 is a triangle wave with equal rising and falling times.
     """
-    t = numpy.linspace(0, 1, int(500 * 440 / hz), endpoint=False)
-    wave = scipy.signal.sawtooth(2 * numpy.pi * 5 * t, width=rising_ramp_width)
-    wave = numpy.resize(wave, (n_samples,))
-    # Sawtooth waves sound very quiet, so multiply peak by 4.
-    return peak * 6 * wave.astype(numpy.int16)
+    length = SAMPLE_RATE / float(hz)
+    omega = numpy.pi * 2 / length
+    xvalues = numpy.arange(int(length)) * omega
+    onecycle = scipy.signal.sawtooth(xvalues, width=1)
+    onecycle = (peak * onecycle).astype(numpy.int16)
+    return numpy.resize(onecycle, (n_samples,))
 
 
-def triangle_wave(hz, peak=SAMPLE_PEAK, rising_ramp_width=0.5, n_samples=SAMPLE_RATE):
+def triangle_wave(hz, peak=SAMPLE_PEAK, n_samples=SAMPLE_RATE):
     """Compute N samples of a triangle wave with given frequency and peak amplitude.
     Defaults to one second.
-    rising_ramp_width is the percentage of the ramp spend rising:
-    .5 is a triangle wave with equal rising and falling times.
     """
-    hz_value = float(hz)
-    num_samples = int(500 * 440 / hz_value)
-    t = numpy.linspace(0, 1, num_samples, endpoint=False)
-    wave = scipy.signal.sawtooth(2 * numpy.pi * 5 * t, width=rising_ramp_width)
-    wave = numpy.resize(wave, (n_samples,))
-    # Use same amplitude as sawtooth_wave for testing
-    return peak * 6 * wave.astype(numpy.int16)
+    length = SAMPLE_RATE / float(hz)
+    omega = numpy.pi * 2 / length
+    xvalues = numpy.arange(int(length)) * omega
+    onecycle = scipy.signal.sawtooth(xvalues, width=0.5)
+    onecycle = (peak * onecycle).astype(numpy.int16)
+    return numpy.resize(onecycle, (n_samples,))
 
 
 def _play_for(sample_wave, ms):
-    """Play the given NumPy array, as a sound, for ms milliseconds."""
-
-    # sounddevice expects float32 samples between -1 and 1
+    """Play the given NumPy sample array through the speakers."""
     normalized_wave = sample_wave.astype(numpy.float32) / SAMPLE_PEAK
-
-    # Play the audio and wait
     sd.play(normalized_wave, SAMPLE_RATE)
     sd.wait()
 
@@ -65,18 +57,70 @@ class Synth(Enum):
     TRIANGLE = triangle_wave
 
 
-def play(tone_or_chord, temperament="equal", synth=Synth.SINE, t=1_000):
-    """Play a tone or chord."""
+def _render(tone_or_chord, temperament="equal", synth=Synth.SINE, t=1_000):
+    """Render a tone or chord to a NumPy sample array.
+
+    Args:
+        tone_or_chord: A :class:`Tone` or :class:`Chord` to render.
+        temperament: Tuning temperament (``"equal"``, ``"pythagorean"``,
+            or ``"meantone"``).
+        synth: Waveform type — ``Synth.SINE``, ``Synth.SAW``, or
+            ``Synth.TRIANGLE``.
+        t: Duration in milliseconds.
+
+    Returns:
+        A NumPy int16 array of audio samples.
+    """
+    n_samples = int(SAMPLE_RATE * t / 1_000)
 
     if isinstance(tone_or_chord, Tone):
-        chord = [synth(tone_or_chord.pitch(temperament=temperament))]
+        waves = [synth(tone_or_chord.pitch(temperament=temperament), n_samples=n_samples)]
     else:
-        chord = [
-            synth(tone.pitch(temperament=temperament))
+        waves = [
+            synth(tone.pitch(temperament=temperament), n_samples=n_samples)
             for tone in tone_or_chord.tones
         ]
 
-    _play_for(sum(chord), ms=t)
+    return sum(waves)
 
 
-#  69 + 12*np.log2(hz_nonneg/440.)
+def play(tone_or_chord, temperament="equal", synth=Synth.SINE, t=1_000):
+    """Play a tone or chord through the speakers.
+
+    Args:
+        tone_or_chord: A :class:`Tone` or :class:`Chord` to play.
+        temperament: Tuning temperament (``"equal"``, ``"pythagorean"``,
+            or ``"meantone"``).
+        synth: Waveform type — ``Synth.SINE``, ``Synth.SAW``, or
+            ``Synth.TRIANGLE``.
+        t: Duration in milliseconds (default 1000).
+
+    Example::
+
+        >>> play(Tone.from_string("A4"), t=1_000)
+        >>> play(Chord.from_name("Am7"), synth=Synth.TRIANGLE, t=2_000)
+    """
+    _play_for(_render(tone_or_chord, temperament=temperament, synth=synth, t=t), ms=t)
+
+
+def save(tone_or_chord, path, temperament="equal", synth=Synth.SINE, t=1_000):
+    """Render a tone or chord and save it as a WAV file.
+
+    Args:
+        tone_or_chord: A :class:`Tone` or :class:`Chord` to render.
+        path: Output file path (e.g. ``"chord.wav"``).
+        temperament: Tuning temperament.
+        synth: Waveform type.
+        t: Duration in milliseconds (default 1000).
+
+    Example::
+
+        >>> save(Chord.from_name("C"), "c_major.wav", t=2_000)
+    """
+    import scipy.io.wavfile
+
+    samples = _render(tone_or_chord, temperament=temperament, synth=synth, t=t)
+    normalized = samples.astype(numpy.float32) / SAMPLE_PEAK
+    # Convert to 16-bit PCM
+    pcm = (normalized * 32767).astype(numpy.int16)
+    scipy.io.wavfile.write(path, SAMPLE_RATE, pcm)

pytheory/scales.py

@@ -236,7 +236,6 @@ class Scale:
         return [self.triad(i) for i in range(unique)]
 
     def degree(self, item: Union[str, int, slice], major: Optional[bool] = None, minor: bool = False) -> Optional[Union[Tone, tuple[Tone, ...]]]:
-        # TODO: cleanup degrees.
 
         # Ensure that both major and minor aren't passed.
         if all((major, minor)):
@@ -653,7 +652,7 @@ class TonedScale:
         try:
             return self._scales[scale]
         except KeyError:
-            pass
+            return None
 
     @property
     def scales(self) -> tuple[str, ...]:

pytheory/systems.py

@@ -24,6 +24,16 @@ class System:
         from . import Tone
         return tuple([Tone.from_tuple(tone) for tone in self.tone_names])
 
+    def resolve_name(self, name: str) -> str | None:
+        """Resolve a note name (including flats) to the canonical name.
+
+        Returns the primary name if found, or None if not recognized.
+        """
+        for names in self.tone_names:
+            if name in names:
+                return names[0]
+        return None
+
 
     @property
     def scales(self):
@@ -105,7 +115,6 @@ class System:
                         yield step
                 else:
                     for i in range(tones):
-                        # TODO: figure out how to make this work with monotonic.
                         yield 1
 
         scale = [

pytheory/tones.py

@@ -71,7 +71,7 @@ class Tone:
     @property
     def exists(self) -> bool:
         """True if this tone's name is found in the associated system."""
-        return self.name in self.system.tones
+        return self.system.resolve_name(self.name) is not None
 
     @property
     def system(self) -> object:
@@ -331,11 +331,17 @@ class Tone:
     def _index(self) -> int:
         """The index of this tone within its associated system's tone list.
 
+        Resolves enharmonic names (e.g. 'Db' → 'C#') before lookup.
+
         Raises:
-            ValueError: If no system is associated with this tone.
+            ValueError: If no system is associated with this tone or
+                the name is not found.
         """
         try:
-            return self.system.tones.index(self.name)
+            canonical = self.system.resolve_name(self.name)
+            if canonical is None:
+                raise ValueError(f"Tone {self.name!r} not found in system")
+            return self.system.tones.index(canonical)
         except AttributeError:
             raise ValueError("Tone index cannot be referenced without a system!")
 

test_pytheory.py

@@ -2622,7 +2622,7 @@ def test_tension_empty():
 
 def test_version():
     import pytheory
-    assert pytheory.__version__ == "0.4.1"
+    assert pytheory.__version__ == "0.6.1"
 
 
 def test_all_exports():
@@ -3647,3 +3647,233 @@ def test_charts_muted_string():
     nc = NamedChord(tone_name="C", quality="")
     fixed = nc.fix_fingering((0, -1, 2))
     assert fixed == (0, None, 2)
+
+
+# ── Flat note support ─────────────────────────────────────────────────────────
+
+def test_flat_tone_from_string():
+    db = Tone.from_string("Db4", system="western")
+    assert db.name == "Db"
+    assert db.octave == 4
+
+
+def test_flat_tone_frequency_matches_sharp():
+    db = Tone.from_string("Db4", system="western")
+    cs = Tone.from_string("C#4", system="western")
+    assert db.frequency == cs.frequency
+
+
+def test_flat_tone_frequency_all_enharmonics():
+    pairs = [("Bb3", "A#3"), ("Eb4", "D#4"), ("Gb4", "F#4"), ("Ab4", "G#4")]
+    for flat, sharp in pairs:
+        f = Tone.from_string(flat, system="western").frequency
+        s = Tone.from_string(sharp, system="western").frequency
+        assert f == s, f"{flat} != {sharp}"
+
+
+def test_flat_tone_arithmetic():
+    db = Tone.from_string("Db4", system="western")
+    result = db + 2
+    assert result.name == "D#"
+    assert result.octave == 4
+
+
+def test_flat_tone_interval():
+    c4 = Tone.from_string("C4", system="western")
+    db4 = Tone.from_string("Db4", system="western")
+    assert db4 - c4 == 1
+
+
+def test_flat_tone_exists():
+    db = Tone.from_string("Db4", system="western")
+    assert db.exists is True
+
+
+def test_flat_tone_index_resolves():
+    db = Tone.from_string("Db4", system="western")
+    cs = Tone.from_string("C#4", system="western")
+    assert db._index == cs._index
+
+
+def test_flat_chord_from_tones():
+    chord = Chord.from_tones("Db", "F", "Ab")
+    assert chord.identify() == "Db major"
+
+
+def test_flat_chord_from_tones_minor():
+    chord = Chord.from_tones("Bb", "Db", "F")
+    assert chord.identify() == "Bb minor"
+
+
+def test_flat_chord_from_tones_seventh():
+    chord = Chord.from_tones("Eb", "G", "Bb", "Db")
+    assert chord.identify() == "Eb dominant 7th"
+
+
+def test_system_resolve_name_sharp():
+    assert SYSTEMS["western"].resolve_name("C#") == "C#"
+
+
+def test_system_resolve_name_flat():
+    assert SYSTEMS["western"].resolve_name("Db") == "C#"
+
+
+def test_system_resolve_name_natural():
+    assert SYSTEMS["western"].resolve_name("C") == "C"
+
+
+def test_system_resolve_name_unknown():
+    assert SYSTEMS["western"].resolve_name("X") is None
+
+
+# ── CLI tests ─────────────────────────────────────────────────────────────────
+
+def test_cli_tone(capsys):
+    from pytheory.cli import cmd_tone
+    import argparse
+    args = argparse.Namespace(note="A4", temperament="equal")
+    cmd_tone(args)
+    out = capsys.readouterr().out
+    assert "440.00" in out
+    assert "A4" in out
+    assert "MIDI" in out
+
+
+def test_cli_tone_pythagorean(capsys):
+    from pytheory.cli import cmd_tone
+    import argparse
+    args = argparse.Namespace(note="C5", temperament="pythagorean")
+    cmd_tone(args)
+    out = capsys.readouterr().out
+    assert "Equal temp" in out
+    assert "cents" in out
+
+
+def test_cli_scale(capsys):
+    from pytheory.cli import cmd_scale
+    import argparse
+    args = argparse.Namespace(tonic="C", mode="major", system="western")
+    cmd_scale(args)
+    out = capsys.readouterr().out
+    assert "C D E F G A B C" in out
+
+
+def test_cli_chord(capsys):
+    from pytheory.cli import cmd_chord
+    import argparse
+    args = argparse.Namespace(notes=["C", "E", "G"])
+    cmd_chord(args)
+    out = capsys.readouterr().out
+    assert "C major" in out
+    assert "Harmony" in out
+    assert "Tension" in out
+
+
+def test_cli_key(capsys):
+    from pytheory.cli import cmd_key
+    import argparse
+    args = argparse.Namespace(tonic="G", mode="major")
+    cmd_key(args)
+    out = capsys.readouterr().out
+    assert "G major" in out
+    assert "Signature" in out
+    assert "Relative" in out
+
+
+def test_cli_fingering(capsys):
+    from pytheory.cli import cmd_fingering
+    import argparse
+    args = argparse.Namespace(chord="Am", capo=0)
+    cmd_fingering(args)
+    out = capsys.readouterr().out
+    assert "Am" in out
+    assert "|--" in out
+
+
+def test_cli_progression(capsys):
+    from pytheory.cli import cmd_progression
+    import argparse
+    args = argparse.Namespace(tonic="C", mode="major", numerals=["I", "V", "vi", "IV"])
+    cmd_progression(args)
+    out = capsys.readouterr().out
+    assert "C major" in out
+    assert "I → V → vi → IV" in out
+
+
+def test_cli_detect(capsys):
+    from pytheory.cli import cmd_detect
+    import argparse
+    args = argparse.Namespace(notes=["C", "E", "G", "A", "D"])
+    cmd_detect(args)
+    out = capsys.readouterr().out
+    assert "C major" in out
+
+
+def test_cli_detect_no_match(capsys):
+    from pytheory.cli import cmd_detect
+    import argparse
+    args = argparse.Namespace(notes=[])
+    cmd_detect(args)
+    out = capsys.readouterr().out
+    assert "Could not detect" in out
+
+
+def test_cli_main_no_args(capsys):
+    from pytheory.cli import main
+    import sys
+    old_argv = sys.argv
+    sys.argv = ["pytheory"]
+    try:
+        main()
+    except SystemExit:
+        pass
+    sys.argv = old_argv
+
+
+# ── Play module tests ─────────────────────────────────────────────────────────
+
+@needs_portaudio
+def test_play_render():
+    """_render produces a numpy array of the right length."""
+    from pytheory.play import _render, Synth, SAMPLE_RATE
+    tone = Tone.from_string("A4", system="western")
+    samples = _render(tone, synth=Synth.SINE, t=500)
+    expected = int(SAMPLE_RATE * 500 / 1000)
+    assert len(samples) == expected
+
+
+@needs_portaudio
+def test_play_render_chord():
+    from pytheory.play import _render, Synth
+    chord = Chord.from_tones("C", "E", "G")
+    samples = _render(chord, synth=Synth.SINE, t=200)
+    assert len(samples) > 0
+
+
+@needs_portaudio
+def test_play_render_all_synths():
+    from pytheory.play import _render, Synth
+    tone = Tone.from_string("C4", system="western")
+    for synth in Synth:
+        samples = _render(tone, synth=synth, t=100)
+        assert len(samples) > 0
+
+
+@needs_portaudio
+def test_play_save(tmp_path):
+    """save() writes a valid WAV file."""
+    from pytheory.play import save, Synth
+    path = tmp_path / "test.wav"
+    tone = Tone.from_string("A4", system="western")
+    save(tone, str(path), synth=Synth.SINE, t=200)
+    assert path.exists()
+    assert path.stat().st_size > 44  # WAV header is 44 bytes
+
+
+@needs_portaudio
+def test_play_save_chord(tmp_path):
+    from pytheory.play import save
+    path = tmp_path / "chord.wav"
+    chord = Chord.from_tones("C", "E", "G")
+    save(chord, str(path), t=200)
+    assert path.exists()