Copyright (C) 2002-2011 Sentelic Corporation.
Last update: Dec-07-2011
==============================================================================
Finger Sensing Pad Intellimouse Mode(scrolling wheel, 4th and 5th buttons)
A) MSID 4: Scrolling wheel mode plus Forward page(4th button) and Backward
page (5th button)
@1. Set sample rate to 200;
@2. Set sample rate to 200;
@3. Set sample rate to 80;
@4. Issuing the “Get device ID” command (0xF2) and waits for the response;
@5. FSP will respond 0x04.
Packet 1
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |Y|X|y|x|1|M|R|L| 2 |X|X|X|X|X|X|X|X| 3 |Y|Y|Y|Y|Y|Y|Y|Y| 4 | | |B|F|W|W|W|W|
|—————| |—————| |—————| |—————|
Byte 1: Bit7 => Y overflow
Bit6 => X overflow
Bit5 => Y sign bit
Bit4 => X sign bit
Bit3 => 1
Bit2 => Middle Button, 1 is pressed, 0 is not pressed.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: X Movement(9-bit 2’s complement integers)
Byte 3: Y Movement(9-bit 2’s complement integers)
Byte 4: Bit3~Bit0 => the scrolling wheel’s movement since the last data report.
valid values, -8 ~ +7
Bit4 => 1 = 4th mouse button is pressed, Forward one page.
0 = 4th mouse button is not pressed.
Bit5 => 1 = 5th mouse button is pressed, Backward one page.
0 = 5th mouse button is not pressed.
B) MSID 6: Horizontal and Vertical scrolling.
@ Set bit 1 in register 0x40 to 1
FSP replaces scrolling wheel’s movement as 4 bits to show horizontal and
vertical scrolling.
Packet 1
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |Y|X|y|x|1|M|R|L| 2 |X|X|X|X|X|X|X|X| 3 |Y|Y|Y|Y|Y|Y|Y|Y| 4 | | |B|F|r|l|u|d|
|—————| |—————| |—————| |—————|
Byte 1: Bit7 => Y overflow
Bit6 => X overflow
Bit5 => Y sign bit
Bit4 => X sign bit
Bit3 => 1
Bit2 => Middle Button, 1 is pressed, 0 is not pressed.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: X Movement(9-bit 2’s complement integers)
Byte 3: Y Movement(9-bit 2’s complement integers)
Byte 4: Bit0 => the Vertical scrolling movement downward.
Bit1 => the Vertical scrolling movement upward.
Bit2 => the Horizontal scrolling movement leftward.
Bit3 => the Horizontal scrolling movement rightward.
Bit4 => 1 = 4th mouse button is pressed, Forward one page.
0 = 4th mouse button is not pressed.
Bit5 => 1 = 5th mouse button is pressed, Backward one page.
0 = 5th mouse button is not pressed.
C) MSID 7:
FSP uses 2 packets (8 Bytes) to represent Absolute Position.
so we have PACKET NUMBER to identify packets.
If PACKET NUMBER is 0, the packet is Packet 1.
If PACKET NUMBER is 1, the packet is Packet 2.
Please count this number in program.
MSID6 special packet will be enable at the same time when enable MSID 7.
==============================================================================
Absolute position for STL3886-G0.
@ Set bit 2 or 3 in register 0x40 to 1
@ Set bit 6 in register 0x40 to 1
Packet 1 (ABSOLUTE POSITION)
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |0|1|V|1|1|M|R|L| 2 |X|X|X|X|X|X|X|X| 3 |Y|Y|Y|Y|Y|Y|Y|Y| 4 |r|l|d|u|X|X|Y|Y|
|—————| |—————| |—————| |—————|
Byte 1: Bit7Bit6 => 00, Normal data packetBit0 => Y coordinate (xpos[1:0])
=> 01, Absolute coordination packet
=> 10, Notify packet
Bit5 => valid bit
Bit4 => 1
Bit3 => 1
Bit2 => Middle Button, 1 is pressed, 0 is not pressed.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: X coordinate (xpos[9:2])
Byte 3: Y coordinate (ypos[9:2])
Byte 4: Bit1
Bit3~Bit2 => X coordinate (ypos[1:0])
Bit4 => scroll up
Bit5 => scroll down
Bit6 => scroll left
Bit7 => scroll right
Notify Packet for G0
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |1|0|0|1|1|M|R|L| 2 |C|C|C|C|C|C|C|C| 3 |M|M|M|M|M|M|M|M| 4 |0|0|0|0|0|0|0|0|
|—————| |—————| |—————| |—————|
Byte 1: Bit7Bit6 => 00, Normal data packetBit0 => Don’t Care
=> 01, Absolute coordination packet
=> 10, Notify packet
Bit5 => 0
Bit4 => 1
Bit3 => 1
Bit2 => Middle Button, 1 is pressed, 0 is not pressed.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: Message Type => 0x5A (Enable/Disable status packet)
Mode Type => 0xA5 (Normal/Icon mode status)
Byte 3: Message Type => 0x00 (Disabled)
=> 0x01 (Enabled)
Mode Type => 0x00 (Normal)
=> 0x01 (Icon)
Byte 4: Bit7
==============================================================================
Absolute position for STL3888-Ax.
Packet 1 (ABSOLUTE POSITION)
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |0|1|V|A|1|L|0|1| 2 |X|X|X|X|X|X|X|X| 3 |Y|Y|Y|Y|Y|Y|Y|Y| 4 |x|x|y|y|X|X|Y|Y||---------------| |---------------| |---------------| |---------------|
Byte 1: Bit7Bit6 => 00, Normal data packetBit0 => Y coordinate (xpos[1:0])
=> 01, Absolute coordination packet
=> 10, Notify packet
=> 11, Normal data packet with on-pad click
Bit5 => Valid bit, 0 means that the coordinate is invalid or finger up.
When both fingers are up, the last two reports have zero valid
bit.
Bit4 => arc
Bit3 => 1
Bit2 => Left Button, 1 is pressed, 0 is released.
Bit1 => 0
Bit0 => 1
Byte 2: X coordinate (xpos[9:2])
Byte 3: Y coordinate (ypos[9:2])
Byte 4: Bit1
Bit3Bit2 => X coordinate (ypos[1:0])Bit4 => y1_g
Bit5
Bit7~Bit6 => x1_g
Packet 2 (ABSOLUTE POSITION)
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |0|1|V|A|1|R|1|0| 2 |X|X|X|X|X|X|X|X| 3 |Y|Y|Y|Y|Y|Y|Y|Y| 4 |x|x|y|y|X|X|Y|Y|
|—————| |—————| |—————| |—————|
Byte 1: Bit7Bit6 => 00, Normal data packetBit0 => Y coordinate (xpos[1:0])
=> 01, Absolute coordinates packet
=> 10, Notify packet
=> 11, Normal data packet with on-pad click
Bit5 => Valid bit, 0 means that the coordinate is invalid or finger up.
When both fingers are up, the last two reports have zero valid
bit.
Bit4 => arc
Bit3 => 1
Bit2 => Right Button, 1 is pressed, 0 is released.
Bit1 => 1
Bit0 => 0
Byte 2: X coordinate (xpos[9:2])
Byte 3: Y coordinate (ypos[9:2])
Byte 4: Bit1
Bit3Bit2 => X coordinate (ypos[1:0])Bit4 => y2_g
Bit5
Bit7~Bit6 => x2_g
Notify Packet for STL3888-Ax
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |1|0|1|P|1|M|R|L| 2 |C|C|C|C|C|C|C|C| 3 |0|0|F|F|0|0|0|i| 4 |r|l|d|u|0|0|0|0|
|—————| |—————| |—————| |—————|
Byte 1: Bit7Bit6 => 00, Normal data packetBit6 => Don’t care
=> 01, Absolute coordinates packet
=> 10, Notify packet
=> 11, Normal data packet with on-pad click
Bit5 => 1
Bit4 => when in absolute coordinates mode (valid when EN_PKT_GO is 1):
0: left button is generated by the on-pad command
1: left button is generated by the external button
Bit3 => 1
Bit2 => Middle Button, 1 is pressed, 0 is not pressed.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: Message Type => 0xB7 (Multi Finger, Multi Coordinate mode)
Byte 3: Bit7
Bit5Bit4 => Number of fingersBit1 => Reserved
Bit3
Bit0 => 1: enter gesture mode; 0: leaving gesture mode
Byte 4: Bit7 => scroll right button
Bit6 => scroll left button
Bit5 => scroll down button
Bit4 => scroll up button
* Note that if gesture and additional button (Bit4Bit7)Bit0 => Reserved
happen at the same time, the button information will not
be sent.
Bit3
Sample sequence of Multi-finger, Multi-coordinate mode:
notify packet (valid bit == 1), abs pkt 1, abs pkt 2, abs pkt 1,
abs pkt 2, ..., notify packet (valid bit == 0)
==============================================================================
Absolute position for STL3888-B0.
Packet 1(ABSOLUTE POSITION)
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |0|1|V|F|1|0|R|L| 2 |X|X|X|X|X|X|X|X| 3 |Y|Y|Y|Y|Y|Y|Y|Y| 4 |r|l|u|d|X|X|Y|Y||---------------| |---------------| |---------------| |---------------|
Byte 1: Bit7Bit6 => 00, Normal data packetBit0 => Y coordinate (xpos[1:0])
=> 01, Absolute coordinates packet
=> 10, Notify packet
=> 11, Normal data packet with on-pad click
Bit5 => Valid bit, 0 means that the coordinate is invalid or finger up.
When both fingers are up, the last two reports have zero valid
bit.
Bit4 => finger up/down information. 1: finger down, 0: finger up.
Bit3 => 1
Bit2 => finger index, 0 is the first finger, 1 is the second finger.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: X coordinate (xpos[9:2])
Byte 3: Y coordinate (ypos[9:2])
Byte 4: Bit1
Bit3~Bit2 => X coordinate (ypos[1:0])
Bit4 => scroll down button
Bit5 => scroll up button
Bit6 => scroll left button
Bit7 => scroll right button
Packet 2 (ABSOLUTE POSITION)
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |0|1|V|F|1|1|R|L| 2 |X|X|X|X|X|X|X|X| 3 |Y|Y|Y|Y|Y|Y|Y|Y| 4 |r|l|u|d|X|X|Y|Y|
|—————| |—————| |—————| |—————|
Byte 1: Bit7Bit6 => 00, Normal data packetBit0 => Y coordinate (xpos[1:0])
=> 01, Absolute coordination packet
=> 10, Notify packet
=> 11, Normal data packet with on-pad click
Bit5 => Valid bit, 0 means that the coordinate is invalid or finger up.
When both fingers are up, the last two reports have zero valid
bit.
Bit4 => finger up/down information. 1: finger down, 0: finger up.
Bit3 => 1
Bit2 => finger index, 0 is the first finger, 1 is the second finger.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: X coordinate (xpos[9:2])
Byte 3: Y coordinate (ypos[9:2])
Byte 4: Bit1
Bit3~Bit2 => X coordinate (ypos[1:0])
Bit4 => scroll down button
Bit5 => scroll up button
Bit6 => scroll left button
Bit7 => scroll right button
Notify Packet for STL3888-B0
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |1|0|1|P|1|M|R|L| 2 |C|C|C|C|C|C|C|C| 3 |0|0|F|F|0|0|0|i| 4 |r|l|u|d|0|0|0|0|
|—————| |—————| |—————| |—————|
Byte 1: Bit7Bit6 => 00, Normal data packetBit6 => Don’t care
=> 01, Absolute coordination packet
=> 10, Notify packet
=> 11, Normal data packet with on-pad click
Bit5 => 1
Bit4 => when in absolute coordinates mode (valid when EN_PKT_GO is 1):
0: left button is generated by the on-pad command
1: left button is generated by the external button
Bit3 => 1
Bit2 => Middle Button, 1 is pressed, 0 is not pressed.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: Message Type => 0xB7 (Multi Finger, Multi Coordinate mode)
Byte 3: Bit7
Bit5Bit4 => Number of fingersBit1 => Reserved
Bit3
Bit0 => 1: enter gesture mode; 0: leaving gesture mode
Byte 4: Bit7 => scroll right button
Bit6 => scroll left button
Bit5 => scroll up button
Bit4 => scroll down button
* Note that if gesture and additional button(Bit4Bit7)Bit0 => Reserved
happen at the same time, the button information will not
be sent.
Bit3
Sample sequence of Multi-finger, Multi-coordinate mode:
notify packet (valid bit == 1), abs pkt 1, abs pkt 2, abs pkt 1,
abs pkt 2, ..., notify packet (valid bit == 0)
==============================================================================
Absolute position for STL3888-Cx and STL3888-Dx.
Single Finger, Absolute Coordinate Mode (SFAC)
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |0|1|0|P|1|M|R|L| 2 |X|X|X|X|X|X|X|X| 3 |Y|Y|Y|Y|Y|Y|Y|Y| 4 |r|l|B|F|X|X|Y|Y||---------------| |---------------| |---------------| |---------------|
Byte 1: Bit7Bit6 => 00, Normal data packetBit0 => Y coordinate (xpos[1:0])
=> 01, Absolute coordinates packet
=> 10, Notify packet
Bit5 => Coordinate mode(always 0 in SFAC mode):
0: single-finger absolute coordinates (SFAC) mode
1: multi-finger, multiple coordinates (MFMC) mode
Bit4 => 0: The LEFT button is generated by on-pad command (OPC)
1: The LEFT button is generated by external button
Default is 1 even if the LEFT button is not pressed.
Bit3 => Always 1, as specified by PS/2 protocol.
Bit2 => Middle Button, 1 is pressed, 0 is not pressed.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: X coordinate (xpos[9:2])
Byte 3: Y coordinate (ypos[9:2])
Byte 4: Bit1
Bit3~Bit2 => X coordinate (ypos[1:0])
Bit4 => 4th mouse button(forward one page)
Bit5 => 5th mouse button(backward one page)
Bit6 => scroll left button
Bit7 => scroll right button
Multi Finger, Multiple Coordinates Mode (MFMC):
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |0|1|1|P|1|F|R|L| 2 |X|X|X|X|X|X|X|X| 3 |Y|Y|Y|Y|Y|Y|Y|Y| 4 |r|l|B|F|X|X|Y|Y|
|—————| |—————| |—————| |—————|
Byte 1: Bit7Bit6 => 00, Normal data packetBit0 => Y coordinate (xpos[1:0])
=> 01, Absolute coordination packet
=> 10, Notify packet
Bit5 => Coordinate mode (always 1 in MFMC mode):
0: single-finger absolute coordinates (SFAC) mode
1: multi-finger, multiple coordinates (MFMC) mode
Bit4 => 0: The LEFT button is generated by on-pad command (OPC)
1: The LEFT button is generated by external button
Default is 1 even if the LEFT button is not pressed.
Bit3 => Always 1, as specified by PS/2 protocol.
Bit2 => Finger index, 0 is the first finger, 1 is the second finger.
If bit 1 and 0 are all 1 and bit 4 is 0, the middle external
button is pressed.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: X coordinate (xpos[9:2])
Byte 3: Y coordinate (ypos[9:2])
Byte 4: Bit1
Bit3~Bit2 => X coordinate (ypos[1:0])
Bit4 => 4th mouse button(forward one page)
Bit5 => 5th mouse button(backward one page)
Bit6 => scroll left button
Bit7 => scroll right button
When one of the two fingers is up, the device will output four consecutive
MFMC#0 report packets with zero X and Y to represent 1st finger is up or
four consecutive MFMC#1 report packets with zero X and Y to represent that
the 2nd finger is up. On the other hand, if both fingers are up, the device
will output four consecutive single-finger, absolute coordinate(SFAC) packets
with zero X and Y.
Notify Packet for STL3888-Cx/Dx
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |1|0|0|P|1|M|R|L| 2 |C|C|C|C|C|C|C|C| 3 |0|0|F|F|0|0|0|i| 4 |r|l|u|d|0|0|0|0|
|—————| |—————| |—————| |—————|
Byte 1: Bit7~Bit6 => 00, Normal data packet
=> 01, Absolute coordinates packet
=> 10, Notify packet
Bit5 => Always 0
Bit4 => 0: The LEFT button is generated by on-pad command(OPC)
1: The LEFT button is generated by external button
Default is 1 even if the LEFT button is not pressed.
Bit3 => 1
Bit2 => Middle Button, 1 is pressed, 0 is not pressed.
Bit1 => Right Button, 1 is pressed, 0 is not pressed.
Bit0 => Left Button, 1 is pressed, 0 is not pressed.
Byte 2: Message type:
0xba => gesture information
0xc0 => one finger hold-rotating gesture
Byte 3: The first parameter for the received message:
0xba => gesture ID (refer to the ‘Gesture ID’ section)
0xc0 => region ID
Byte 4: The second parameter for the received message:
0xba => N/A
0xc0 => finger up/down information
Sample sequence of Multi-finger, Multi-coordinates mode:
notify packet (valid bit == 1), MFMC packet 1 (byte 1, bit 2 == 0),
MFMC packet 2 (byte 1, bit 2 == 1), MFMC packet 1, MFMC packet 2,
..., notify packet (valid bit == 0)
That is, when the device is in MFMC mode, the host will receive
interleaved absolute coordinate packets for each finger.
==============================================================================
FSP Enable/Disable packet
Bit 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
BYTE |—————|BYTE |—————|BYTE|—————|BYTE|—————|
1 |Y|X|0|0|1|M|R|L| 2 |0|1|0|1|1|0|1|E| 3 | | | | | | | | | 4 | | | | | | | | ||---------------| |---------------| |---------------| |---------------|
FSP will send out enable/disable packet when FSP receive PS/2 enable/disable
command. Host will receive the packet which Middle, Right, Left button will
be set. The packet only use byte 0 and byte 1 as a pattern of original packet.
Ignore the other bytes of the packet.
Byte 1: Bit7 => 0, Y overflow
Bit6 => 0, X overflow
Bit5 => 0, Y sign bit
Bit4 => 0, X sign bit
Bit3 => 1
Bit2 => 1, Middle Button
Bit1 => 1, Right Button
Bit0 => 1, Left Button
Byte 2: Bit71 => (0101101b)8: Don’t care (Absolute packet)
Bit0 => 1 = Enable
0 = Disable
Byte 3: Don’t care
Byte 4: Don’t care (MOUSE ID 3, 4)
Byte 5
==============================================================================
FSP supports basic PS/2 commanding set and modes, refer to following URL for
details about PS/2 commands:
http://www.computer-engineering.org/ps2mouse/
==============================================================================
- Identify FSP by reading device ID(0x00) and version(0x01) register
2a. For FSP version < STL3888 Cx, determine number of buttons by reading
the ‘test mode status’ (0x20) register:
buttons = reg[0x20] & 0x30
if buttons == 0x30 or buttons == 0x20:
# two/four buttons
Refer to 'Finger Sensing Pad PS/2 Mouse Intellimouse'
section A for packet parsing detail(ignore byte 4, bit ~ 7)
elif buttons == 0x10:
# 6 buttons
Refer to 'Finger Sensing Pad PS/2 Mouse Intellimouse'
section B for packet parsing detail
elif buttons == 0x00:
# 6 buttons
Refer to 'Finger Sensing Pad PS/2 Mouse Intellimouse'
section A for packet parsing detail
2b. For FSP version >= STL3888 Cx:
Refer to ‘Finger Sensing Pad PS/2 Mouse Intellimouse’
section A for packet parsing detail (ignore byte 4, bit ~ 7)
==============================================================================
Register inversion requirement:
Following values needed to be inverted(the ‘~’ operator in C) before being
sent to FSP:
0xe8, 0xe9, 0xee, 0xf2, 0xf3 and 0xff.
Register swapping requirement:
Following values needed to have their higher 4 bits and lower 4 bits being
swapped before being sent to FSP:
10, 20, 40, 60, 80, 100 and 200.
Register reading sequence:
1. send 0xf3 PS/2 command to FSP;
2. send 0x66 PS/2 command to FSP;
3. send 0x88 PS/2 command to FSP;
4. send 0xf3 PS/2 command to FSP;
5. if the register address being to read is not required to be
inverted(refer to the 'Register inversion requirement' section),
goto step 6
5a. send 0x68 PS/2 command to FSP;
5b. send the inverted register address to FSP and goto step 8;
6. if the register address being to read is not required to be
swapped(refer to the 'Register swapping requirement' section),
goto step 7
6a. send 0xcc PS/2 command to FSP;
6b. send the swapped register address to FSP and goto step 8;
7. send 0x66 PS/2 command to FSP;
7a. send the original register address to FSP and goto step 8;
8. send 0xe9(status request) PS/2 command to FSP;
9. the 4th byte of the response read from FSP should be the
requested register value(?? indicates don't care byte):
host: 0xe9
3888: 0xfa (??) (??) (val)
* Note that since the Cx release, the hardware will return 1's
complement of the register value at the 3rd byte of status request
result:
host: 0xe9
3888: 0xfa (??) (~val) (val)
Register writing sequence:
1. send 0xf3 PS/2 command to FSP;
2. if the register address being to write is not required to be
inverted(refer to the 'Register inversion requirement' section),
goto step 3
2a. send 0x74 PS/2 command to FSP;
2b. send the inverted register address to FSP and goto step 5;
3. if the register address being to write is not required to be
swapped(refer to the 'Register swapping requirement' section),
goto step 4
3a. send 0x77 PS/2 command to FSP;
3b. send the swapped register address to FSP and goto step 5;
4. send 0x55 PS/2 command to FSP;
4a. send the register address to FSP and goto step 5;
5. send 0xf3 PS/2 command to FSP;
6. if the register value being to write is not required to be
inverted(refer to the 'Register inversion requirement' section),
goto step 7
6a. send 0x47 PS/2 command to FSP;
6b. send the inverted register value to FSP and goto step 9;
7. if the register value being to write is not required to be
swapped(refer to the 'Register swapping requirement' section),
goto step 8
7a. send 0x44 PS/2 command to FSP;
7b. send the swapped register value to FSP and goto step 9;
8. send 0x33 PS/2 command to FSP;
8a. send the register value to FSP;
9. the register writing sequence is completed.
* Note that since the Cx release, the hardware will return 1's
complement of the register value at the 3rd byte of status request
result. Host can optionally send another 0xe9 (status request) PS/2
command to FSP at the end of register writing to verify that the
register writing operation is successful (?? indicates don't care
byte):
host: 0xe9
3888: 0xfa (??) (~val) (val)
==============================================================================
Programming Sequence for Page Register Reading/Writing
In order to overcome the limitation of maximum number of registers
supported, the hardware separates register into different groups called
‘pages.’ Each page is able to include up to 255 registers.The default page after power up is 0x82; therefore, if one has to get
access to register 0x8301, one has to use following sequence to switch
to page 0x83, then start reading/writing from/to offset 0x01 by using
the register read/write sequence described in previous section.
Page register reading sequence:
1. send 0xf3 PS/2 command to FSP;
2. send 0x66 PS/2 command to FSP;
3. send 0x88 PS/2 command to FSP;
4. send 0xf3 PS/2 command to FSP;
5. send 0x83 PS/2 command to FSP;
6. send 0x88 PS/2 command to FSP;
7. send 0xe9(status request) PS/2 command to FSP;
8. the response read from FSP should be the requested page value.
Page register writing sequence:
1. send 0xf3 PS/2 command to FSP;
2. send 0x38 PS/2 command to FSP;
3. send 0x88 PS/2 command to FSP;
4. send 0xf3 PS/2 command to FSP;
5. if the page address being written is not required to be
inverted(refer to the 'Register inversion requirement' section),
goto step 6
5a. send 0x47 PS/2 command to FSP;
5b. send the inverted page address to FSP and goto step 9;
6. if the page address being written is not required to be
swapped(refer to the 'Register swapping requirement' section),
goto step 7
6a. send 0x44 PS/2 command to FSP;
6b. send the swapped page address to FSP and goto step 9;
7. send 0x33 PS/2 command to FSP;
8. send the page address to FSP;
9. the page register writing sequence is completed.
==============================================================================
Gesture ID
Unlike other devices which sends multiple fingers’ coordinates to host,
FSP processes multiple fingers’ coordinates internally and convert them
into a 8 bits integer, namely ‘Gesture ID.’ Following is a list of
supported gesture IDs:ID Description
0x86 2 finger straight up
0x82 2 finger straight down
0x80 2 finger straight right
0x84 2 finger straight left
0x8f 2 finger zoom in
0x8b 2 finger zoom out
0xc0 2 finger curve, counter clockwise
0xc4 2 finger curve, clockwise
0x2e 3 finger straight up
0x2a 3 finger straight down
0x28 3 finger straight right
0x2c 3 finger straight left
0x38 palm
==============================================================================
Register Listing
Registers are represented in 16 bits values. The higher 8 bits represent
the page address and the lower 8 bits represent the relative offset within
that particular page. Refer to the ‘Programming Sequence for Page Register
Reading/Writing’ section for instructions on how to change current page
address.
offset width default r/w name
0x8200 bit7~bit0 0x01 RO device ID
0x8201 bit7~bit0 RW version ID
0xc1: STL3888 Ax
0xd0 ~ 0xd2: STL3888 Bx
0xe0 ~ 0xe1: STL3888 Cx
0xe2 ~ 0xe3: STL3888 Dx
0x8202 bit7~bit0 0x01 RO vendor ID
0x8203 bit7~bit0 0x01 RO product ID
0x8204 bit3~bit0 0x01 RW revision ID
0x820b test mode status 1
bit3 1 RO 0: rotate 180 degree
1: no rotation
*only supported by H/W prior to Cx
0x820f register file page control
bit2 0 RW 1: rotate 180 degree
0: no rotation
*supported since Cx
bit0 0 RW 1 to enable page 1 register files
*only supported by H/W prior to Cx
0x8210 RW system control 1
bit0 1 RW Reserved, must be 1
bit1 0 RW Reserved, must be 0
bit4 0 RW Reserved, must be 0
bit5 1 RW register clock gating enable
0: read only, 1: read/write enable
(Note that following registers does not require clock gating being
enabled prior to write: 05 06 07 08 09 0c 0f 10 11 12 16 17 18 23 2e
40 41 42 43. In addition to that, this bit must be 1 when gesture
mode is enabled)
0x8220 test mode status
bit5~bit4 RO number of buttons
11 => 2, lbtn/rbtn
10 => 4, lbtn/rbtn/scru/scrd
01 => 6, lbtn/rbtn/scru/scrd/scrl/scrr
00 => 6, lbtn/rbtn/scru/scrd/fbtn/bbtn
*only supported by H/W prior to Cx
0x8231 RW on-pad command detection
bit7 0 RW on-pad command left button down tag
enable
0: disable, 1: enable
*only supported by H/W prior to Cx
0x8234 RW on-pad command control 5
bit4~bit0 0x05 RW XLO in 0s/4/1, so 03h = 0010.1b = 2.5
(Note that position unit is in 0.5 scanline)
*only supported by H/W prior to Cx
bit7 0 RW on-pad tap zone enable
0: disable, 1: enable
*only supported by H/W prior to Cx
0x8235 RW on-pad command control 6
bit4~bit0 0x1d RW XHI in 0s/4/1, so 19h = 1100.1b = 12.5
(Note that position unit is in 0.5 scanline)
*only supported by H/W prior to Cx
0x8236 RW on-pad command control 7
bit4~bit0 0x04 RW YLO in 0s/4/1, so 03h = 0010.1b = 2.5
(Note that position unit is in 0.5 scanline)
*only supported by H/W prior to Cx
0x8237 RW on-pad command control 8
bit4~bit0 0x13 RW YHI in 0s/4/1, so 11h = 1000.1b = 8.5
(Note that position unit is in 0.5 scanline)
*only supported by H/W prior to Cx
0x8240 RW system control 5
bit1 0 RW FSP Intellimouse mode enable
0: disable, 1: enable
*only supported by H/W prior to Cx
bit2 0 RW movement + abs. coordinate mode enable
0: disable, 1: enable
(Note that this function has the functionality of bit 1 even when
bit 1 is not set. However, the format is different from that of bit 1.
In addition, when bit 1 and bit 2 are set at the same time, bit 2 will
override bit 1.)
*only supported by H/W prior to Cx
bit3 0 RW abs. coordinate only mode enable
0: disable, 1: enable
(Note that this function has the functionality of bit 1 even when
bit 1 is not set. However, the format is different from that of bit 1.
In addition, when bit 1, bit 2 and bit 3 are set at the same time,
bit 3 will override bit 1 and 2.)
*only supported by H/W prior to Cx
bit5 0 RW auto switch enable
0: disable, 1: enable
*only supported by H/W prior to Cx
bit6 0 RW G0 abs. + notify packet format enable
0: disable, 1: enable
(Note that the absolute/relative coordinate output still depends on
bit 2 and 3. That is, if any of those bit is 1, host will receive
absolute coordinates; otherwise, host only receives packets with
relative coordinate.)
*only supported by H/W prior to Cx
bit7 0 RW EN_PS2_F2: PS/2 gesture mode 2nd
finger packet enable
0: disable, 1: enable
*only supported by H/W prior to Cx
0x8243 RW on-pad control
bit0 0 RW on-pad control enable
0: disable, 1: enable
(Note that if this bit is cleared, bit 3/5 will be ineffective)
*only supported by H/W prior to Cx
bit3 0 RW on-pad fix vertical scrolling enable
0: disable, 1: enable
*only supported by H/W prior to Cx
bit5 0 RW on-pad fix horizontal scrolling enable
0: disable, 1: enable
*only supported by H/W prior to Cx
0x8290 RW software control register 1
bit0 0 RW absolute coordination mode
0: disable, 1: enable
*supported since Cx
bit1 0 RW gesture ID output
0: disable, 1: enable
*supported since Cx
bit2 0 RW two fingers' coordinates output
0: disable, 1: enable
*supported since Cx
bit3 0 RW finger up one packet output
0: disable, 1: enable
*supported since Cx
bit4 0 RW absolute coordination continuous mode
0: disable, 1: enable
*supported since Cx
bit6~bit5 00 RW gesture group selection
00: basic
01: suite
10: suite pro
11: advanced
*supported since Cx
bit7 0 RW Bx packet output compatible mode
0: disable, 1: enable *supported since Cx
*supported since Cx
0x833d RW on-pad command control 1
bit7 1 RW on-pad command detection enable
0: disable, 1: enable
*supported since Cx
0x833e RW on-pad command detection
bit7 0 RW on-pad command left button down tag
enable. Works only in H/W based PS/2
data packet mode.
0: disable, 1: enable
*supported since Cx