fceux/documentation/tech/cpu/nessound.txt

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The NES sound channel guide 1.8
Written by Brad Taylor.
btmine@hotmail.com
Last updated: July 27th, 2000.
All results were obtained by studying prior information available (from
nestech 1.00, and postings on NESDev from miscellanious people), and through
a series of experiments conducted by me. Results acquired by individuals
prior to my reverse-engineering have been double checked, and final results
have been confirmed. Credit is due to those individual(s) who contributed
any information in regards to the the miscellanious sound channels wihtin
the NES.
A special thanks goes out to Matthew Conte, for his expertise on
pseudo-random number generation (amoung other things), which allowed for the
full reverse engineering of the NES's noise channel to take place. Without
his help, I would still be trying to find a needle in a haystack, as far as
the noise's method of pseudo-random number generation goes. Additionally,
his previous findings / reverse engineering work on the NES's sound hardware
really got the ball of NES sound emulation rolling. If it weren't for Matt's
original work, this document wouldn't exist.
Thanks to Kentaro Ishihara, for his excellent work on finding the difference
in upward frequency sweep between the 2 square wave channels.
****************
* Introduction *
****************
The 2A03 (NES's integrated CPU) has 4 internal channels to it that have the
ability to generate semi-analog sound, for musical playback purposes. These
channels are 2 square wave channels, one triangle wave channel, and a noise
generation channel. This document will go into full detail on every aspect
of the operation and timing of the mentioned sound channels.
*******************
* Channel details *
*******************
Each channel has different characteristics to it that make up it's
operation.
The square channel(s) have the ability to generate a square wave frequency
in the range of 54.6 Hz to 12.4 KHz. It's key features are frequency sweep
abilities, and output duty cycle adjustment.
The triangle wave channel has the ability to generate an output triangle
wave with a resolution of 4-bits (16 steps), in the range of 27.3 Hz to 55.9
KHz. The key features this channel has is it's analog triangle wave output,
and it's linear counter, which can be set to automatically disable the
channel's sound after a certain period of time has gone by.
The noise channel is used for producing random frequencys, which results in
a "noisey" sounding output. Output frequencys can range anywhere from 29.3
Hz to 447 KHz. It's key feature is it's pseudo- random number generator,
which generates the random output frequencys heard by the channel.
*****************
* Frame counter *
*****************
The 2A03 has an internal frame counter. It has the ability to generate 60 Hz
(1/1 framerate), 120 Hz (1/2 framerate), and 240 Hz (1/4 framerate) signals,
used by some of the sound hardware. The 1/4 framerate is calculated by
taking twice the CPU clock speed (3579545.454545 Hz), and dividing it by
14915 (i.e., the divide-by-14915 counter is decremented on the rising AND
falling edge of the CPU's clock signal).
************************
* Sound hardware delay *
************************
After resetting the 2A03, the first time any sound channel(s) length counter
contains a non-zero value (channel is enabled), there will be a 2048 CPU
clock cycle delay before any of the sound hardware is clocked. After the 2K
clock cycles go by, the NES sound hardware will be clocked normally. This
phenomenon only occurs prior to a system reset, and only occurs during the
first 2048 CPU clocks for any sound channel prior to a sound channel being
enabled.
The information in regards to this delay is only provided to keep this
entire document persistently accurate on the 2A03's sound hardware, but may
not be 100% accurate in itself. I haven't done much tests on the behaviour
of this delay (mainly because I don't care, as I view it as a inconvenience
anyway), so that's why I believe there could be some inaccuracies.
************************
* Register Assignments *
************************
The sound hardware internal to the 2A03 has been designated these special
memory addresses in the CPU's memory map.
$4000-$4003 Square wave 1
$4004-$4007 Square wave 2 (identical to the first, except for upward
frequency sweeps (see "sweep unit" section))
$4008-$400B Triangle
$400C-$400F Noise
$4015 Channel enable / length counter status
Note that $4015 is the only R/W register. All others are write only (attempt
to read them will most likely result in a returned 040H, due to heavy
capacitance on the NES's data bus). Reading a "write only" register, will
have no effect on the specific register, or channel.
Every sound channel has 4 registers affiliated with it. The description of
the register sets are as follows:
+----------------+
| Register set 1 |
+----------------+
$4000(sq1)/$4004(sq2)/$400C(noise) bits
---------------------------------------
0-3 volume / envelope decay rate
4 envelope decay disable
5 length counter clock disable / envelope decay looping enable
6-7 duty cycle type (unused on noise channel)
$4008(tri) bits
---------------
0-6 linear counter load register
7 length counter clock disable / linear counter start
+----------------+
| Register set 2 |
+----------------+
$4001(sq1)/$4005(sq2) bits
--------------------------
0-2 right shift amount
3 decrease / increase (1/0) wavelength
4-6 sweep update rate
7 sweep enable
$4009(tri)/$400D(noise) bits
----------------------------
0-7 unused
+----------------+
| Register set 3 |
+----------------+
$4002(sq1)/$4006(sq2)/$400A(Tri) bits
-------------------------------------
0-7 8 LSB of wavelength
$400E(noise) bits
-----------------
0-3 playback sample rate
4-6 unused
7 random number type generation
+----------------+
| Register set 4 |
+----------------+
$4003(sq1)/$4007(sq2)/$400B(tri)/$400F(noise) bits
--------------------------------------------------
0-2 3 MS bits of wavelength (unused on noise channel)
3-7 length counter load register
+--------------------------------+
| length counter status register |
+--------------------------------+
$4015(read)
-----------
0 square wave channel 1
1 square wave channel 2
2 triangle wave channel
3 noise channel
4 DMC (see "DMC.TXT" for details)
5-6 unused
7 IRQ status of DMC (see "DMC.TXT" for details)
+-------------------------+
| channel enable register |
+-------------------------+
$4015(write)
------------
0 square wave channel 1
1 square wave channel 2
2 triangle wave channel
3 noise channel
4 DMC channel (see "DMC.TXT" for details)
5-7 unused
************************
* Channel architecture *
************************
This section will describe the internal components making up each individual
channel. Each component will then be described in full detail.
Device Triangle Noise Square
------ -------- ------ ------
triangle step generator X
linear counter X
programmable timer X X X
length counter X X X
4-bit DAC X X X
volume/envelope decay unit X X
sweep unit X
duty cycle generator X
wavelength converter X
random number generator X
+-------------------------+
| Triangle step generator |
+-------------------------+
This is a 5-bit, single direction counter, and it is only used in the
triangle channel. Each of the 4 LSB outputs of the counter lead to one input
on a corresponding mutually exclusive XNOR gate. The 4 XNOR gates have been
strobed together, which results in the inverted representation of the 4 LSB
of the counter appearing on the outputs of the gates when the strobe is 0,
and a non-inverting action taking place when the strobe is 1. The strobe is
naturally connected to the MSB of the counter, which effectively produces on
the output of the XNOR gates a count sequence which reflects the scenario of
a near- ideal triangle step generator (D,E,F,F,E,D,...,2,1,0,0,1,2,...). At
this point, the outputs of the XNOR gates will be fed into the input of a
4-bit DAC.
This 5-bit counter will be halted whenever the Triangle channel's length or
linear counter contains a count of 0. This results in a "latching"
behaviour; the counter will NOT be reset to any definite state.
On system reset, this counter is loaded with 0.
The counter's clock input is connected directly to the terminal count output
pin of the 11-bit programmable timer in the triangle channel. As a result of
the 5-bit triangle step generator, the output triangle wave frequency will
be 32 times less than the frequency of the triangle channel's programmable
timer is set to generate.
+----------------+
| Linear counter |
+----------------+
The linear counter is only found in the triangle channel. It is a 7-bit
presettable down counter, with a decoded output condition of 0 available
(not exactly the same as terminal count). Here's the bit assignments:
$4008 bits
----------
0-6 bits 0-6 of the linear counter load register (NOT the linear counter
itself)
7 linear counter start
The counter is clocked at 240 Hz (1/4 framerate), and the calculated length
in frames is 0.25*N, where N is the 7-bit loaded value. The counter is
always being clocked, except when 0 appears on the output of the counter. At
this point, the linear counter & triangle step counter clocks signals are
disabled, which results in both counters latching their current state (the
linear counter will stay at 0, and the triangle step counter will stop, and
the channel will be silenced due to this).
The linear counter has 2 modes: load, and count. When the linear counter is
in load mode, it essentially becomes transparent (i.e. whatever value is
currently in, or being written to $4008, will appear on the output of the
counter). Because of this, no count action can occur in load mode. When the
mode changes from load to count, the counter will now latch the value
currently in it, and start counting down from there. In the count mode, the
current value of $4008 is ignored by the counter (but still retained in
$4008). Described below is how the mode of the linear counter is set:
Writes to $400B
---------------
cur mode
--- ----
1 load
0 load (during the write cycle), count
Cur is the current state of the MSB of $4008.
Writes to $4008
---------------
old new mode
--- --- ----
0 X count
1 0 no change (during the write cycle), count
1 1 no change
Old and new represent the state(s) of the MSB of $4008. Old is the value
being replaced in the MSB of $4008 on the write, and new is the value
replacing the old one.
"no change" indicates that the mode of the linear counter will not change
from the last.
+--------------------+
| Programmable timer |
+--------------------+
The programmable timer is a 11-bit presettable down counter, and is found in
the square, triangle, and noise channel(s). The bit assignments are as
follows:
$4002(sq1)/$4006(sq2)/$400A(Tri) bits
-------------------------------------
0-7 represent bits 0-7 of the 11-bit wavelength
$4003(sq1)/$4007(sq2)/$400B(Tri) bits
-------------------------------------
0-2 represent bits 8-A of the 11-bit wavelength
Note that on the noise channel, the 11 bits are not available directly. See
the wavelength converter section, for more details.
The counter has automatic syncronous reloading upon terminal count
(count=0), therefore the counter will count for N+1 (N is the 11-bit loaded
value) clock cycles before arriving at terminal count, and reloading. This
counter will typically be clocked at the 2A03's internal 6502 speed (1.79
MHz), and produces an output frequency of 1.79 MHz/(N+1). The terminal
count's output spike length is typically no longer than half a CPU clock.
The TC signal will then be fed to the appropriate device for the particular
sound channel (for square, this terminal count spike will lead to the duty
cycle generator. For the triangle, the spike will be fed to the triangle
step generator. For noise, this signal will go to the random number
generator unit).
+----------------+
| Length counter |
+----------------+
The length counter is found in all sound channels. It is essentially a 7-bit
down counter, and is conditionally clocked at a frequency of 60 Hz.
When the length counter arrives at a count of 0, the counter will be stopped
(stay on 0), and the appropriate channel will be silenced.
The length counter clock disable bit, found in all the channels, can also be
used to halt the count sequence of the length counter for the appropriate
channel, by writing a 1 out to it. A 0 condition will permit counting
(unless of course, the counter's current count = 0). Location(s) of the
length counter clock disable bit:
$4000(sq1)/$4004(sq2)/$400C(noise) bits
---------------------------------------
5 length counter clock disable
$4008(tri) bits
---------------
7 length counter clock disable
To load the length counter with a specified count, a write must be made out
to the length register. Location(s) of the length register:
$4003(sq1)/$4007(sq2)/$400B(tri)/$400F(noise) bits
--------------------------------------------------
3-7 length
The 5-bit length value written, determines what 7-bit value the length
counter will start counting from. A conversion table here will show how the
values are translated.
+-----------------------+
| bit3=0 |
+-------+---------------+
| |frames |
|bits +-------+-------+
|4-6 |bit7=0 |bit7=1 |
+-------+-------+-------+
|0 |05 |06 |
|1 |0A |0C |
|2 |14 |18 |
|3 |28 |30 |
|4 |50 |60 |
|5 |1E |24 |
|6 |07 |08 |
|7 |0E |10 |
+-------+-------+-------+
+---------------+
| bit3=1 |
+-------+-------+
|bits | |
|4-7 |frames |
+-------+-------+
|0 |7F |
|1 |01 |
|2 |02 |
|3 |03 |
|4 |04 |
|5 |05 |
|6 |06 |
|7 |07 |
|8 |08 |
|9 |09 |
|A |0A |
|B |0B |
|C |0C |
|D |0D |
|E |0E |
|F |0F |
+-------+-------+
The length counter's real-time status for each channel can be attained. A 0
is returned for a zero count status in the length counter (channel's sound
is disabled), and 1 for a non-zero status. Here's the bit description of the
length counter status register:
$4015(read)
-----------
0 length counter status of square wave channel 1
1 length counter status of square wave channel 2
2 length counter status of triangle wave channel
3 length counter status of noise channel
4 length counter status of DMC (see "DMC.TXT" for details)
5-6 unused
7 IRQ status of DMC (see "DMC.TXT" for details)
Writing a 0 to the channel enable register will force the length counters to
always contain a count equal to 0, which renders that specific channel
disabled (as if it doesn't exist). Writing a 1 to the channel enable
register disables the forced length counter value of 0, but will not change
the count itself (it will still be whatever it was prior to the writing of
1).
Bit description of the channel enable register:
$4015(write)
------------
0 enable square wave channel 1
1 enable square wave channel 2
2 enable triangle wave channel
3 enable noise channel
4 enable DMC channel (see "DMC.TXT" for details)
5-7 unused
Note that all 5 used bits in this register will be set to 0 upon system
reset.
+-----------+
| 4-bit DAC |
+-----------+
This is just a standard 4-bit DAC with 16 steps of output voltage
resolution, and is used by all 4 sound channels.
On the 2A03, square wave 1 & 2 are mixed together, and are available via pin
1. Triangle & noise are available on pin 2. These analog outputs require a
negative current source, to attain linear symmetry on the various output
voltage levels generated by the channel(s) (moreover, to get the sound to be
audible). Since the NES just uses external 100 ohm pull-down resistors, this
results in the output waveforms being of very small amplitude, but with
minimal linearity asymmetry.
+------------------------------+
| Volume / envelope decay unit |
+------------------------------+
The volume / envelope decay hardware is found only in the square wave and
noise channels.
$4000(sq1)/$4004(sq2)/$400C(noise)
----------------------------------
0-3 volume / envelope decay rate
4 envelope decay disable
5 envelope decay looping enable
When the envelope decay disable bit (bit 4) is set (1), the current volume
value (bits 0-3) is sent directly to the channel's DAC. However, depending
on certain conditions, this 4-bit volume value will be ignored, and a value
of 0 will be sent to the DAC instead. This means that while the channel is
enabled (producing sound), the output of the channel (what you'll hear from
the DAC) will either be the 4-bit volume value, or 0. This also means that a
4-bit volume value of 0 will result in no audible sound. These conditions
are as follows:
- When hardware in the channel wants to disable it's sound output (like the
length counter, or sweep unit (square channels only)).
- On the negative portion of the output frequency signal coming from the
duty cycle / random number generator hardware (square wave channel / noise
channel).
When the envelope decay disable bit is cleared, bits 0-3 now control the
envelope decay rate, and an internal 4-bit down counter (hereon the envelope
decay counter) now controls the channel's volume level. "Envelope decay" is
used to describe the action of the channel's audio output volume starting
from a certain value, and decreasing by 1 at a fixed (linear) rate (which
produces a "fade-out" sounding effect). This fixed decrement rate is
controlled by the envelope decay rate (bits 0-3). The calculated decrement
rate is 240Hz/(N+1), where N is any value between $0-$F.
When the channel's envelope decay counter reaches a value of 0, depending on
the status of the envelope decay looping enable bit (bit 5, which is shared
with the length counter's clock disable bit), 2 different things will
happen:
bit 5 action
----- ------
0 The envelope decay count will stay at 0 (channel silenced).
1 The envelope decay count will wrap-around to $F (upon the next clock
cycle). The envelope decay counter will then continue to count down
normally.
Only a write out to $4003/$4007/$400F will reset the current envelope decay
counter to a known state (to $F, the maximum volume level) for the
appropriate channel's envelope decay hardware. Otherwise, the envelope decay
counter is always counting down (by 1) at the frequency currently contained
in the volume / envelope decay rate bits (even when envelope decays are
disabled (setting bit 4)), except when the envelope decay counter contains a
value of 0, and envelope decay looping (bit 5) is disabled (0).
+------------+
| Sweep unit |
+------------+
The sweep unit is only found in the square wave channels. The controls for
the sweep unit have been mapped in at $4001 for square 1, and $4005 for
square 2.
The controls
------------
Bit 7 when this bit is set (1), sweeping is active. This results in
real-time increasing or decreasing of the the current wavelength value (the
audible frequency will decrease or increase, respectively). The wavelength
value in $4002/3 ($4006/7) is constantly read & updated by the sweep.
Modifying the contents of $4002/3 will be immediately audible, and will
result in the sweep now starting from this new wavelength value.
Bits 6-4 These 3 bits represent the sweep refresh rate, or the frequency at
which $4002/3 is updated with the new calculated wavelength. The refresh
rate frequency is 120Hz/(N+1), where N is the value written, between 0 and
7.
Bit 3 This bit controls the sweep mode. When this bit is set (1), sweeps
will decrease the current wavelength value, as a 0 will increase the current
wavelength.
Bits 2-0 These bits control the right shift amount of the new calculated
sweep update wavelength. Code that shows how the sweep unit calculates a new
sweep wavelength is as follows:
bit 3
-----
0 New = Wavelength + (Wavelength >> N)
1 New = Wavelength - (Wavelength >> N) (minus an additional 1, if using
square wave channel 1)
where N is the the shift right value, between 0-7.
Note that in decrease mode, for subtracting the 2 values:
1's compliment (NOT) is being used for square wave channel 1
2's compliment (NEG) is being used for square wave channel 2
This information is currently the only known difference between the 2 square
wave channels.
On each sweep refresh clock, the Wavelength register will be updated with
the New value, but only if all 3 of these conditions are met:
- bit 7 is set (sweeping enabled)
- the shift value (which is N in the formula) does not equal to 0
- the channel's length counter contains a non-zero value
Notes
-----
There are certain conditions that will cause the sweep unit to silence the
channel, and halt the sweep refresh clock (which effectively stops sweep
action, if any). Note that these conditions pertain regardless of any sweep
refresh rate values, or if sweeping is enabled/disabled (via bit 7).
- an 11-bit wavelength value less than $008 will cause this condition
- if the sweep unit is currently set to increase mode, the New calculated
wavelength value will always be tested to see if a carry (bit $B) was
generated or not (if sweeping is enabled, this carry will be examined before
the Wavelength register is updated) from the shift addition calculation. If
carry equals 1, the channel is silenced, and sweep action is halted.
+----------------------+
| Duty cycle generator |
+----------------------+
The duty cycle generator takes the fequency produced from the 11-bit
programmable timer, and uses a 4 bit counter to produce 4 types of duty
cycles. The output frequency is then 1/16 that of the programmable timer.
The duty cycle hardware is only found in the square wave channels. The bit
assignments are as follows:
$4000(sq1)/$4004(sq2)
---------------------
6-7 Duty cycle type
duty (positive/negative)
val in clock cycles
--- ---------------
00 2/14
01 4/12
10 8/ 8
11 12/ 4
Where val represents bits 6-7 of $4000/$4004.
The output frequency at this point will now be fed to the volume/envelope
decay hardware.
+----------------------+
| Wavelength converter |
+----------------------+
The wavelength converter is only used in the noise channel. It is used to
convert a given 4-bit value to an 11-bit wavelength, which then is sent to
the noise's own programmable timer. Here is the bit descriptions:
$400E bits
----------
0-3 The 4-bit value to be converted
Below is a conversion chart that shows what 4-bit value will represent the
11-bit wavelength to be fed to the channel's programmable timer:
value octave scale CPU clock cycles (11-bit wavelength+1)
----- ------ ----- --------------------------------------
0 15 A 002
1 14 A 004
2 13 A 008
3 12 A 010
4 11 A 020
5 11 D 030
6 10 A 040
7 10 F 050
8 10 C 065
9 9 A 07F
A 9 D 0BE
B 8 A 0FE
C 8 D 17D
D 7 A 1FC
E 6 A 3F9
F 5 A 7F2
Octave and scale information is provided for the music enthusiast programmer
who is more familiar with notes than clock cycles.
+-------------------------+
| Random number generator |
+-------------------------+
The noise channel has a 1-bit pseudo-random number generator. It's based on
a 15-bit shift register, and an exclusive or gate. The generator can produce
two types of random number sequences: long, and short. The long sequence
generates 32,767-bit long number patterns. The short sequence generates
93-bit long number patterns. The 93-bit mode will generally produce higher
sounding playback frequencys on the channel. Here is the bit that controls
the mode:
$400E bits
----------
7 mode
If mode=0, then 32,767-bit long number sequences will be produced (32K
mode), otherwise 93-bit long number sequences will be produced (93-bit
mode).
The following diagram shows where the XOR taps are taken off the shift
register to produce the 1-bit pseudo-random number sequences for each mode.
mode <-----
---- EDCBA9876543210
32K **
93-bit * *
The current result of the XOR will be transferred into bit position 0 of the
SR, upon the next shift cycle. The 1-bit random number output is taken from
pin E, is inverted, then is sent to the volume/envelope decay hardware for
the noise channel. The shift register is shifted upon recieving 2 clock
pulses from the programmable timer (the shift frequency will be half that of
the frequency from the programmable timer (one octave lower)).
On system reset, this shift register is loaded with a value of 1.