TMS320DM644x DMSoC
VLYNQ Port
User's Guide
Literature Number: SPRUE36A
September 2007
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Contents
Preface ............................................................................................................................... 7
1
Introduction................................................................................................................ 9
1.1
1.2
1.3
1.4
Purpose of the Peripheral....................................................................................... 9
Features ........................................................................................................... 9
Functional Block Diagram ..................................................................................... 10
Industry Standard(s) Compliance Statement ............................................................... 10
2
Peripheral Architecture .............................................................................................. 11
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
2.9
Clock Control.................................................................................................... 11
Signal Descriptions ............................................................................................. 12
Pin Multiplexing ................................................................................................. 12
Protocol Description............................................................................................ 12
VLYNQ Functional Description ............................................................................... 13
Initialization ...................................................................................................... 16
Auto-Negotiation ................................................................................................ 16
Serial Interface Width Configuration ......................................................................... 16
Address Translation ............................................................................................ 17
2.10 Flow Control..................................................................................................... 20
2.11 Reset Considerations .......................................................................................... 21
2.12 Interrupt Support................................................................................................ 21
2.13 DMA Event Support ............................................................................................ 23
2.14 Power Management............................................................................................ 24
2.15 Emulation Considerations ..................................................................................... 24
VLYNQ Port Registers................................................................................................ 25
3
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
3.9
Revision Register (REVID) .................................................................................... 26
Control Register (CTRL)....................................................................................... 27
Status Register (STAT) ........................................................................................ 29
Interrupt Priority Vector Status/Clear Register (INTPRI) .................................................. 31
Interrupt Status/Clear Register (INTSTATCLR) ............................................................ 31
Interrupt Pending/Set Register (INTPENDSET) ............................................................ 32
Interrupt Pointer Register (INTPTR) ......................................................................... 32
Transmit Address Map Register (XAM)...................................................................... 33
Receive Address Map Size 1 Register (RAMS1) .......................................................... 34
3.10 Receive Address Map Offset 1 Register (RAMO1) ........................................................ 34
3.11 Receive Address Map Size 2 Register (RAMS2) .......................................................... 35
3.12 Receive Address Map Offset 2 Register (RAMO2) ........................................................ 35
3.13 Receive Address Map Size 3 Register (RAMS3) .......................................................... 36
3.14 Receive Address Map Offset 3 Register (RAMO3) ........................................................ 36
3.15 Receive Address Map Size 4 Register (RAMS4) .......................................................... 37
3.16 Receive Address Map Offset 4 Register (RAMO4) ........................................................ 37
3.17 Chip Version Register (CHIPVER) ........................................................................... 38
3.18 Auto Negotiation Register (AUTNGO) ....................................................................... 38
Remote Configuration Registers ................................................................................. 39
4
Appendix A VLYNQ Protocol Specifications ........................................................................ 40
Special 8b/10b Code Groups ................................................................................. 40
A.1
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A.2
A.3
A.4
Supported Ordered Sets....................................................................................... 40
VLYNQ 2.0 Packet Format .................................................................................... 41
VLYNQ 2.X Packets............................................................................................ 43
Appendix B Write/Read Performance .................................................................................. 45
B.1
Write Performance.............................................................................................. 45
Read Performance ............................................................................................. 47
B.2
Appendix C Revision History ............................................................................................. 48
4
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List of Figures
1
VLYNQ Port Functional Block Diagram ................................................................................. 10
External Clock Block Diagram............................................................................................ 11
Internal Clock Block Diagram............................................................................................. 11
VLYNQ Module Structure ................................................................................................. 13
Write Operations ........................................................................................................... 14
Read Operations ........................................................................................................... 15
Example Address Memory Map .......................................................................................... 18
Interrupt Generation Mechanism Block Diagram....................................................................... 22
Revision Register (REVID)................................................................................................ 26
Control Register (CTRL)................................................................................................... 27
Status Register (STAT).................................................................................................... 29
Interrupt Priority Vector Status/Clear Register (INTPRI) .............................................................. 31
Interrupt Status/Clear Register (INTSTATCLR) ........................................................................ 31
Interrupt Pending/Set Register (INTPENDSET)........................................................................ 32
Interrupt Pointer Register (INTPTR) ..................................................................................... 32
Transmit Address Map Register (XAM) ................................................................................. 33
Receive Address Map Size 1 Register (RAMS1) ...................................................................... 34
Receive Address Map Offset 1 Register (RAMO1).................................................................... 34
Receive Address Map Size 2 Register (RAMS2) ...................................................................... 35
Receive Address Map Offset 2 Register (RAMO2).................................................................... 35
Receive Address Map Size 3 Register (RAMS3) ...................................................................... 36
Receive Address Map Offset 3 Register (RAMO3).................................................................... 36
Receive Address Map Size 4 Register (RAMS4) ...................................................................... 37
Receive Address Map Offset 4 Register (RAMO4).................................................................... 37
Chip Version Register (CHIPVER)....................................................................................... 38
Auto Negotiation Register (AUTNGO)................................................................................... 38
Packet Format (10-bit Symbol Representation)........................................................................ 41
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
A-1
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List of Figures
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List of Tables
1
VLYNQ Port Pins........................................................................................................... 12
Serial Interface Width...................................................................................................... 16
Address Translation Example (Single Mapped Region) .............................................................. 18
Address Translation Example (Single Mapped Region) .............................................................. 19
VLYNQ Register Address Space......................................................................................... 25
VLYNQ Port Controller Registers ........................................................................................ 25
Revision Register (REVID) Field Descriptions ......................................................................... 26
Control Register (CTRL) Field Descriptions ............................................................................ 27
Status Register (STAT) Field Descriptions ............................................................................. 29
Interrupt Priority Vector Status/Clear Register (INTPRI) Field Descriptions........................................ 31
Interrupt Status/Clear Register (INTSTATCLR) Field Descriptions.................................................. 31
Interrupt Pending/Set Register (INTPENDSET) Field Descriptions ................................................. 32
Interrupt Pointer Register (INTPTR) Field Descriptions............................................................... 32
Address Map Register (XAM) Field Descriptions ...................................................................... 33
Receive Address Map Size 1 Register (RAMS1) Field Descriptions................................................ 34
Receive Address Map Offset 1 Register (RAMO1) Field Descriptions.............................................. 34
Receive Address Map Size 2 Register (RAMS2) Field Descriptions................................................ 35
Receive Address Map Offset 2 Register (RAMO2) Field Descriptions.............................................. 35
Receive Address Map Size 3 Register (RAMS3) Field Descriptions................................................ 36
Receive Address Map Offset 3 Register (RAMO3) Field Descriptions.............................................. 36
Receive Address Map Size 4 Register (RAMS4) Field Descriptions................................................ 37
Receive Address Map Offset 4 Register (RAMO4) Field Descriptions.............................................. 37
Chip Version Register (CHIPVER) Field Descriptions................................................................. 38
Auto Negotiation Register (AUTNGO) Field Descriptions ............................................................ 38
VLYNQ Port Remote Controller Registers.............................................................................. 39
Special 8b/10b Code Groups ............................................................................................. 40
Supported Ordered Sets .................................................................................................. 40
Packet Format (10-bit Symbol Representation) Description.......................................................... 42
Scaling Factors ............................................................................................................. 46
Expected Throughput (VLYNQ Interface Running at 76.5 MHZ and 99 MHZ) .................................... 46
Relative Performance with Various Latencies.......................................................................... 47
Document Revision History ............................................................................................... 48
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
A-1
A-2
A-3
B-1
B-2
B-3
C-1
6
List of Tables
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Preface
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Read This First
About This Document
This document describes the VLYNQ™ communications interface port in the TMS320DM644x Digital
Media System-on-Chip (DMSoC).
Notational Conventions
This document uses the following conventions.
•
Hexadecimal numbers are shown with the suffix h. For example, the following number is 40
hexadecimal (decimal 64): 40h.
•
Registers in this document are shown in figures and described in tables.
–
Each register figure shows a rectangle divided into fields that represent the fields of the register.
Each field is labeled with its bit name, its beginning and ending bit numbers above, and its
read/write properties below. A legend explains the notation used for the properties.
–
Reserved bits in a register figure designate a bit that is used for future device expansion.
Related Documentation From Texas Instruments
The following documents describe the TMS320DM644x Digital Media System-on-Chip (DMSoC). Copies
of these documents are available on the Internet at www.ti.com. Tip: Enter the literature number in the
The current documentation that describes the DM644x DMSoC, related peripherals, and other technical
SPRUE14 — TMS320DM644x DMSoC ARM Subsystem Reference Guide. Describes the ARM
subsystem in the TMS320DM644x Digital Media System-on-Chip (DMSoC). The ARM subsystem is
designed to give the ARM926EJ-S (ARM9) master control of the device. In general, the ARM is
responsible for configuration and control of the device; including the DSP subsystem, the video
processing subsystem, and a majority of the peripherals and external memories.
SPRUE15 — TMS320DM644x DMSoC DSP Subsystem Reference Guide. Describes the digital signal
processor (DSP) subsystem in the TMS320DM644x Digital Media System-on-Chip (DMSoC).
SPRUE19 — TMS320DM644x DMSoC Peripherals Overview Reference Guide. Provides an overview
and briefly describes the peripherals available on the TMS320DM644x Digital Media
System-on-Chip (DMSoC).
SPRAA84 — TMS320C64x to TMS320C64x+ CPU Migration Guide. Describes migrating from the
Texas Instruments TMS320C64x digital signal processor (DSP) to the TMS320C64x+ DSP. The
objective of this document is to indicate differences between the two cores. Functionality in the
devices that is identical is not included.
SPRU732 — TMS320C64x/C64x+ DSP CPU and Instruction Set Reference Guide. Describes the CPU
architecture, pipeline, instruction set, and interrupts for the TMS320C64x and TMS320C64x+ digital
signal processors (DSPs) of the TMS320C6000 DSP family. The C64x/C64x+ DSP generation
comprises fixed-point devices in the C6000 DSP platform. The C64x+ DSP is an enhancement of
the C64x DSP with added functionality and an expanded instruction set.
SPRU871 — TMS320C64x+ DSP Megamodule Reference Guide. Describes the TMS320C64x+ digital
signal processor (DSP) megamodule. Included is a discussion on the internal direct memory access
(IDMA) controller, the interrupt controller, the power-down controller, memory protection, bandwidth
management, and the memory and cache.
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Preface
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Related Documentation From Texas Instruments
SPRAAA6 — EDMA v3.0 (EDMA3) Migration Guide for TMS320DM644x DMSoC. Describes migrating
from the Texas Instruments TMS320C64x digital signal processor (DSP) enhanced direct memory
access (EDMA2) to the TMS320DM644x Digital Media System-on-Chip (DMSoC) EDMA3. This
document summarizes the key differences between the EDMA3 and the EDMA2 and provides
guidance for migrating from EDMA2 to EDMA3.
Trademarks
VLYNQ is a trademark of Texas Instruments.
8
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User's Guide
SPRUE36A–September 2007
VLYNQ Port
1
Introduction
1.1 Purpose of the Peripheral
The VLYNQ™ communications interface port is a low pin count, high-speed, point-to-point serial interface
in the TMS320DM644x Digital Media System-on-Chip (DMSoC) used for connecting to host processors
and other VLYNQ-compatible devices. The VLYNQ port is a full-duplex serial bus where transmit and
receive operations occur separately and simultaneously without interference.
VLYNQ enables the extension of an internal bus segment to one or more external physical devices. The
external devices are mapped to local physical address space and appear as if they are on the internal bus
of the DM644x DMSoC. The external devices must also have a VLYNQ interface.
VLYNQ uses a simple block code (8b/10b) packet format and supports in-band flow control so that no
extra terminals are needed to indicate that overflow conditions might occur.
The VLYNQ module on the DM644x DMSoC serializes a write transaction to the remote/external device
and transfers the write via the VLYNQ port (TX pins). The remote VLYNQ module deserializes the
transaction on the other side.
The read transactions to the remote/external device follow the same process, but the remote device's
VLYNQ module serializes the read return data and transfers it to the VLYNQ port (RX pins). The read
return data is finally deserialized and released to the device internal bus.
The external device can also initiate read and write transactions.
1.2 Features
The general features of the VLYNQ port are:
•
•
Low pin count (10 pin interface, scalable to as low as 3 pins)
No tri-state signals
–
–
All signals are dedicated and driven by only one device
Necessary to allow support for high-speed PHYs
•
•
Scalable Performance
–
–
Programmable frequency and 1 to 4 bits for TX and RX data
Performance increases linearly as the data port width increases
Simple packet-based transfer protocol for memory-mapped access
–
–
–
–
Write request/data packet
Read request packet
Read response data packet
Interrupt request packet
•
Auto width negotiation
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Introduction
•
Symmetric Operations
–
Transmit (TX) pins on the first device connect to the receive (RX) pins on the second device and
vice-versa.
–
–
Data pin widths are automatically detected after reset
Re-request packets, response packets, and flow control information are all multiplexed and sent
across the same physical pins.
–
Supports both host/peripheral and peer-to-peer communication models
•
•
Simple block code packet formatting (8b/10b)
Supports in-band and flow control
–
–
–
No extra pins are needed
Allows the receiver to momentarily throttle the transmitter back when overflow is about to occur
Uses the special built-in block code capability to interleave flow control information seamlessly with
user data
•
•
•
Automatic packet formatting optimizations
Internal loopback modes are provided
Connects to legacy VLYNQ devices
1.3 Functional Block Diagram
Figure 1. VLYNQ Port Functional Block Diagram
VLYNQ module
Slave
config
bus
VLYNQ_SCRUN
VLYNQ_CLOCK
VLYNQ_TXD[3:0]
VLYNQ_RXD[3:0]
ARM/EDMA
Interface
VLYNQ register
access
CPU/EDMA initiated
transfers to
remote device
Master
config
bus
System
memory
Interface
Off chip
(remote)
device access
VLQINT
INT31
ARM interrupt
controller
1.4 Industry Standard(s) Compliance Statement
VLYNQ is an interface defined by Texas Instruments and does not conform to any other industry standard.
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Peripheral Architecture
2
Peripheral Architecture
This section discusses the architecture and basic functions of the VLYNQ peripheral.
2.1 Clock Control
The module's serial clock direction and frequency are software configurable through the CLKDIR and
CLKDIV bits in the VLYNQ control register (CTRL). The VLYNQ serial clock can be sourced from the
internal system clock (CLKDIR = 1) or by an external clock source (CLKDIR = 0) for its serial operations.
The CLKDIV bit can divide the serial clock (1/1 - 1/8) down when the internal clock is selected as the
source. The serial clock is not affected by the CLKDIV bit values, if the serial clock is externally sourced.
The reset value of the CLKDIR bit is 0 (external clock source).
Figure 2. External Clock Block Diagram
DMxxx device
VLYNQ
VLYNQ device
CLKDIR=0
VLYNQ
VLYNQ.CLK
CLKDIR=0
Figure 3. Internal Clock Block Diagram
DMxxx device
VLYNQ
VLYNQ device
CLKDIR=1
VLYNQ
VLYNQ
internal
sys clk
VLYNQ.CLK
Don't
care
CLKDIR=0
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Peripheral Architecture
2.2 Signal Descriptions
The VLYNQ module on the DM644x device is configurable for a 1 to 4 bit-wide RX/TX. Chip-level pin
multiplexing registers control the configuration. See the pin multiplexing information in the device-specific
data manual.
If the configured width does not match the number of transmit/receive lines that are available on the
remote device, negotiation between the two VLYNQ devices automatically configures the width (see
Table 1. VLYNQ Port Pins
Pin Name
Signal Name
I/O Description
VLYNQ_CLOCK VLYNQ serial clock
I/O The VLYNQ reference clock supports the internally or externally generated
clock.
VLYNQ_SCRUN VLYNQ serial clock
run request
I/O The VLYNQ serial clock run request allows remote requests for the VLYNQ
serial clock to be turned off for system power management.
Low: The request VLYNQ serial clock is active.
(Active low)
High: The VLYNQ serial clock is requested to be high when all transactions are
complete.
VLYNQ_RXD[0:3] VLYNQ receive data
VLYNQ_TXD[0:3] VLYNQ transmit data
I
VLYNQ receive data is synchronous with the VLYNQ serial clock.
VLYNQ transmit data is synchronous with the VLYNQ serial clock.
O
2.3 Pin Multiplexing
The VLYNQ signals share pins on the processor package with other processor functions. The VLYNQ
module pins are not enabled at reset. In order to change the default function of device pins at reset, the
pin multiplexing registers (PINMUXn) must be configured appropriately. See the pin multiplexing
information in the device-specific data manual for more detailed information on the processor pin
multiplexing and configuration registers.
2.4 Protocol Description
VLYNQ relies on 8b/10b block coding to minimize the number of serial pins and allows for in-band packet
delineation and control.
Appendix A provides general information on 8b/10b coding definitions and their implementation within the
VLYNQ module in the DM644x device.
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Peripheral Architecture
2.5 VLYNQ Functional Description
The VLYNQ core supports both host-to-peripheral and peer-to-peer communication models and is
Figure 4. VLYNQ Module Structure
System clock
VLYNQ clock
Outbound
command
FIFO
Slave
config bus
interface
Address
Outbound
8B/10B
Serial
TxSM
Serializer
translation
commands
encoding
TxData
Serial
TxClk
(FIFO3)
Return
data
FIFO
Registers
(FIFO2)
Return
data
FIFO
Serial
RxClk
(FIFO0)
Master
config bus
interface
Inbound
command
FIFO
Address
Inbound
8B/10B
Serial
RxSM
Deserializer
translation
commands
decoding
RxData
(FIFO1)
The VLYNQ core module implements two 32-bit configuration bus interfaces. Transmit operations and
control register access require the slave configuration bus interface. The master configuration bus
interface is required for receive operations. Converting to and from the 32-bit bus to the external serial
interface requires serializer and deserializer blocks.
8b/10b block coding encodes data on the serial interface. Frame delineation, initialization, and flow control
use special overhead code groups.
FIFOs buffer the entire burst on the bus for maximum performance, thus minimizing bus latency. Using
write operations of each VLYNQ module interfaced is typically recommended to ensure the best
performance on both directions of the link.
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Peripheral Architecture
2.5.1
Write Operations
Write requests that initiate from the slave configuration bus interface of the local device write to the
outbound command (CMD) FIFO. Data is subsequently read from the FIFO and encapsulated in a write
request packet. The address is translated, and the packet is encoded and serialized before being
transmitted to remote device. The remote device subsequently deserializes and decodes the receive data
and writes it into the inbound CMD FIFO. A write operation initiates on the remote device’s master
configuration bus interface after reading the address and data from the FIFO.
Figure 5. Write Operations
System clock
VLYNQ clock
Serial
Slave
config bus
interface
Outbound
command
FIFO
TxData
Address
Outbound
8B/10B
TxSM
Serializer
translation
commands
encoding
Return
data
FIFO
Registers
Local VLYNQ
Return
data
FIFO
Master
config bus
interface
Inbound
command
FIFO
Address
Inbound
8B/10B
Serial
RxSM
Deserializer
translation
commands
decoding
RxData
System clock
VLYNQ Clock
Serial
Slave
config bus
interface
Outbound
command
FIFO
TxData
Address
Outbound
8B/10B
TxSM
Serializer
translation
commands
encoding
Return
data
FIFO
Registers
Remote VLYNQ
Return
data
FIFO
Serial
Master
config bus
interface
Inbound
command
FIFO
RxData
Address
Inbound
8B/10B
RxSM
Deserializer
translation
commands
decoding
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Peripheral Architecture
2.5.2
Read Operations
Read requests from the slave configuration bus interface are written to the outbound CMD FIFO (similar to
the write requests). Data is subsequently read from the FIFO and encapsulated into a read request
packet. The packet is encoded and serialized before it is transmitted to the remote device. Next, the
remote device deserializes, decodes the receive data, and writes the receive data to the inbound CMD
FIFO. After reading the address from the FIFO, a master configuration bus interface read operation
initiates in the remote device. When the remote master configuration bus interface receives the read data,
the data is written to the return data FIFO before it is encoded and serialized. When the receive data
reaches the local VLYNQ module, it is deserialized, decoded, and written to the return data FIFO (local
device). Finally, the read data is transferred on the local device’s slave configuration interface.
The data flow between two connected VLYNQ devices with read requests that originate from the DM644x
dotted arrows.
Figure 6. Read Operations
System clock
VLYNQ Clock
Serial
Outbound
command
FIFO
Slave
config bus
interface
TxData
Address
Outbound
8B/10B
TxSM
Serializer
translation
commands
encoding
Return
data
FIFO
Registers
Local VLYNC
Return
data
FIFO
Serial
Inbound
command
FIFO
RxData
Master
config bus
interface
Address
Inbound
8B/10B
RxSM
Deserializer
translation
commands
decoding
System clock
VLYNQ Clock
Serial
Slave
config bus
interface
Outbound
command
FIFO
TxData
Address
Outbound
8B/10B
TxSM
Serializer
translation
commands
encoding
Return
data
FIFO
Registers
Remote VLYNQ
Return
data
FIFO
Serial
Master
config bus
interface
Inbound
command
FIFO
RxData
Address
Inbound
8B/10B
RxSM
Deserializer
translation
commands
decoding
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Peripheral Architecture
Note: Not servicing read operations results in deadlock. The only way to recover from a deadlock
situation is to perform a hard reset. Read operations are typically not serviced due to read
requests that are issued to a non-existent remote VLYNQ device or they are not serviced
due to trying to perform reads on the VLYNQ memory map prior to establishing the link.
Generally, you should not use read operations to transfer data packets since the serial nature of the
2.6 Initialization
Since VLYNQ devices can be controlled solely over the serial interface (that is, no local CPU exists), an
automatic reliable initialization sequence (without user configuration) establishes a connection between
two VLYNQ devices, just after a VLYNQ module is enabled and auto-negotiation occurs. Auto-negotiation
Bit 0 in the VLYNQ status register (LINK bit) is set to 1 when a link is established.
A link pulse timer generates a periodic link code every 2048 serial clock cycles. The link is lost when time
expires and no link code has been detected during a period of 4096 serial clock cycles.
2.7 Auto-Negotiation
Auto-negotiation occurs after reset. It involves placing a negotiation protocol in the outbound data and
processing the inbound data to establish connection information. The width of the data pins on the serial
interface is automatically determined at reset as a part of the initialization sequence. For a connection
between two VLYNQ devices of version 2.0 and later (VLYNQ on DM644x device is version 2.6), the
negotiation protocol using the available serial pins is used to convey the maximum width capability of each
device. The TXD data pins are not required to have the same width as the RXD data pins.
The auto width negotiation does not occur until after completion of the VLYNQ 1.x legacy width
configuration, which involves a period of 2000 VLYNQ 1.x system clock cycles for connection to VLYNQ
1.x devices. After the VLYNQ 1.x has determined its width, it receives the VLYNQ2.x auto width
negotiation protocol. The VLYNQ 1.x device does not recognize this protocol and transmits error codes
over the serial interface. The received error codes allow the VLYNQ 2.x devices to determine how many
serial pins are valid on the connected VLYNQ 1.x device.
Once the width is established, VLYNQ further identifies the version (version 1.x or version 2.x ) of the
remote VLYNQ. This better determines the capabilities of the connected VLYNQ device. This is software
readable via the VLYNQ auto-negotiation register (AUTNGO), bit 16 (0 = Ver 1.x , 1 = Ver 2.x), after the
link has been established.
2.8 Serial Interface Width Configuration
The VLYNQWD bit in the pin multiplexing register 0 (PINMUX0) controls the data width on the DM644x
Table 2. Serial Interface Width
VLYNQWD
VLYNQ Data Width
00
01
11
10
VLYNQ TXD[0] , VLYNQ RXD[0]
VLYNQ TXD[0:1] , VLYNQ RXD[0:1]
VLYNQ TXD[0:2] , VLYNQ RXD[0:2]
VLYNQ TXD[0:3] , VLYNQ RXD[0:3]
For detailed information on the processor pin multiplexing and configuration register, see the pin
multiplexing information in the device-specific data manual.
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Peripheral Architecture
2.9 Address Translation
Remote VLYNQ device(s) are memory mapped to the local (host) device’s address space when a link is
established (this is similar to any other on-chip peripherals). Enumerating the VLYNQ devices (single or
multiple) into a coherent memory map for accessing each device is part of the initialization sequence.
After the enumeration, the host (local) device can access the remote device address map using local
device addresses. The VLYNQ module in the host device manages the address translation of the local
address to the remote address. A remote VLYNQ device is mapped to the local device’s address via the
address map registers (TX address map, RX address map size n, RX address map offset n, where n = 1
to 4). The transmit side has a contiguous map; the size of the map is the same as the remote device map.
In the local device, the address of the VLYNQ remote memory map in the local configuration space is the
transmit address accessing remote devices over the serial interface. The address of the VLYNQ remote
memory map is programmed in the TX address map register (XAM). When the local device transmits, first
it strips off the transmit address offset in the local device memory map. Then, the local device sends the
data with an address offset from the transmit address.
VLYNQ allows each receive packet address to be translated into one of the four mapped regions. The size
and offset of each memory region must be aligned to 32-bit words. No restriction is placed on
programming the size or on the offset of each mapped region, as long as the total memory that is mapped
into these one to four regions is not more then 64 MBytes.
Note: Care should be taken while programming the receive address map size register (RAMSn)
and the receive address map offset register (RAMOn) values. These registers should be
programmed with valid address locations and memory size to match the device
specifications. See the Memory Map Summary and the System Interconnect sections in your
device-specific data manual to identify the valid memory regions that can be accessed by an
off-chip peer device through the VLYNQ interface.
The transmitted address is used to determine which remote mapped region is being accessed at the
remote device. This is achieved by summing each memory size sequentially until the memory size is
larger than the transmitted address. The last memory size that is added is the targeted region. A memory
size and an offset specify the remote map. The remote map is programmed in the RX address map size
register (RAMSn) and in the RX address map offset register (RAMOn) in the remote device.
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Peripheral Architecture
Figure 7. Example Address Memory Map
Remote
DMxxx device (local)
VLYNQ device
0000:0000
Map region 1
0400:0000
(0C00:0000 on CONFIG bus)
03FF:FFFF
0400:0000
Map region 1
Map region 2
07FF:FFFF
0800:0000
0400:00FF
0500:0000
0500:FFFF
0B00:0000
Map region 2
Map region 3
0800:00FF
0800:0100
Map region 3
0801:00FF
0801:0100
Map region 4
Map region 4
0841:00FF
0B3F:FFFF
The following shows an example illustrating the address translation used in each VLYNQ module.
Address bits [31:26] are not used for address translation to remote devices on the DM644x device.
Table 3 illustrates address map register configuration when the DM644x device is transmitting data to the
remote device.
Table 3. Address Translation Example (Single Mapped Region)
Register
DM644x VLYNQ Module
0000 : 0000h
Remote VLYNQ Module
Do not care
TX Address Map
RX Address Map Size 1
RX Address Map Offset 1
Do not care
0000 : 0100h
Do not care
0800 : 0000h
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DM644x VLYNQ Module:
0C00 : 0054h Initial address at the slave configuration bus
0000 : 0054h Initial address [25:0] at the slave configuration bus interface
subtract
0000 : 0000h TX address map register (there is no need to change the reset value of the
DM644x device for this register)
0000 : 0054h
Remote VLYNQ Module:
0000 : 0054h Initial address from the RX serial interface
compare
0000 : 0100h RX address map size 1 register
0000 : 0054h
add
0800 : 0000h RX address map offset 1 register
0800 : 0054h Translated address to remote device
The local address 0C00 : 0054h (or 0000 0054h) was translated to 0800 : 0054h on the remote VLYNQ
Table 4 illustrates the address map register configuration when the DM644x device is receiving data from
the remote device.
Table 4. Address Translation Example (Single Mapped Region)
Register
DM644x VLYNQ Module
Do not care
Remote VLYNQ Module
0400 : 0000h
Do not care
TX Address Map
RX Address Map Size 1
RX Address Map Offset 1
RX Address Map Size 2
RX Address Map Offset 2
0000 : 0100h
0200 : 0000h
Do not care
0000 : 0100h
Do not care
8200 : 0000h
Do not care
Remote VLYNQ Module:
0400 : 0154h Initial address at the slave configuration bus for the remote device
0400 : 0000h TX address map register
subtract
0000 : 0154h Translated address to remote device via serial interface
DM644x VLYNQ Module:
0000 : 0154h Initial address from the RX serial interface
compare
0000 : 0100h RX address map size 1 register
0000 : 0154h The RX packet address is greater than the value in the RX address map size 1
register
compare
0000 : 0200h RX address map size 1 register + RX address map size 2
Since the RX packet address < the RX address map size 1 register +
RX address map size 2 register
add
8200 : 0000h RX address map offset 2 register
0000 : 0100h RX address map size 1 register
8200 : 0054h Translated address to DM644x device
subtract
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Peripheral Architecture
Example 1. Address Translation Example
The remote address 0x 0400 : 0154 (or 0x0000 0054) was translated to 0x 8200 : 0054 on the DM644x
(local) device in this example.
The translated address for packets received on the serial interface is determined as follows:
If (RX Packet Address < RX Address Map Size 1 Register) {
Translated Address = RX Packet Address +
RX Address Map Offset 1 Register
} else if (RX Packet Address < (RX Address Map Size 1 Register +
RX Address Map Size 2 Register)) {
Translated Address = RX Packet Address +
RX Address Map Offset 2 Register -
RX Address Map Size 1 Register
} else if (RX Packet Address < (RX Address Map Size 1 Register +
RX Address Map Size 2 Register +
RX Address Map Size 3 Register)) {
Translated Address = RX Packet Address +
RX Address Map Offset 3 Register -
RX Address Map Size 1 Register -
RX Address Map Size 2 Register
} else if (RX Packet Address < (RX Address Map Size 1 Register +
RX Address Map Size 2 Register +
RX Address Map Size 3 Register +
RX Address Map Size 4 Register)) {
Translated Address = RX Packet Address +
RX Address Map Offset 4 Register -
RX Address Map Size 1 Register -
RX Address Map Size 2 Register -
RX Address Map Size 3 Register
} else {
Translated Address = 0x0
}
2.10 Flow Control
The VLYNQ module includes flow control features. The VLYNQ module automatically generates flow
control enable requests, /P/, when the RX/inbound FIFOs (FIFO1 and FIFO2) resources are consumed.
The FIFOs can take up to 16 32-bit words.
The remote device will begin transmitting idles, /I/, starting on the first byte boundary following reception of
the request. When sufficient RX FIFO resources have been made available, a flow control disable request,
/C/, is transmitted to the remote device. In response, the remote device will resume transmission of data.
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Peripheral Architecture
2.11 Reset Considerations
2.11.1 Software Reset Considerations
Peripheral clock and reset control is done through the power and sleep controller (PSC) module that is
included with the device. For more information, refer to the power management section (Section 2.14).
Additionally, there is a software reset (the reset bit in the VLYNQ control register, CTRL) within the
peripheral itself. Writing a 1 to the reset bit resets all of the internal state machines of the VLYNQ module,
the serial interface is disabled, and the link is lost. The VLYNQ module remains in reset until the software
clears the bit.
Note: When setting the reset bit, the VLYNQ status register (STAT) value is the only value that is
set to the default value. All of the other VLYNQ memory-mapped registers retain their values
prior to the software reset.
2.11.2 Hardware Reset Considerations
When a hardware reset occurs, the VLYNQ peripheral resets its register values to the default values and
the serial interface is disabled. After a hardware reset, the VLYNQ memory mapped registers and any
chip-level registers that are associated with VLYNQ (for example, pin multiplexing registers) must be
configured appropriately before data transmission can resume.
CAUTION
Be cautious when only resetting one of the VLYNQ devices after two or more
VLYNQ devices have established a link. If only one of the VLYNQ devices is in
reset, then no data activity can occur across the serial interface during the time
of reset.
2.12 Interrupt Support
2.12.1 Interrupt Events and Requests
The VLYNQ module interrupt VLQINT is mapped to the ARM interrupt controller (ARM INT31). For more
information on the ARM interrupt controller (AINTC), see the TMS320DM644x DMSoC ARM Subsystem
Reference Guide (SPRUE14).
Interrupts generate when bits are set in the VLYNQ interrupt pending/set register (INTPENDSET). Bits are
set in the INTPENDSET register when any of the following occur:
•
•
•
Writing directly to the INTPENDSET
Remote interrupt (via the serial interrupt packet)
Serial bus error
When the VLYNQ interrupt pending/set register (INTPENDSET) is a non-zero value, the method of
forwarding the interrupt status depends on the state of the INTLOCAL bit in the VLYNQ control register
(CTRL).
When INTLOCAL = 0, the contents of INTPENDSET are inserted into an interrupt packet and sent over
the serial interface. When packet transmission completes, the associated bits clear in INTPENDSET.
When INTLOCAL = 1, bits in INTPENDSET transfer to the VLYNQ interrupt status/clear register
(INTSTATCLR). The logical-OR of all of the bits in INTSTATCLR is driven onto the interrupt line, causing
the VLYNQINT to pulse.
If the system writes to INTSTATCLR while interrupts are still pending, a new VLQINT interrupt is
generated.
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Peripheral Architecture
Figure 8. Interrupt Generation Mechanism Block Diagram
Serial interrupt
CPU writes
packet from
remote device
Serial bus error
(LERROR/RERROR)
VLYNQ control register (CTRL)
14
VLYNQ interrupt
pending/set register
(INTPENDSET)
0
INTLOCAL
INTLOCAL=1
INTLOCAL=0
VLYNQ
Status/clear
register
(INTSTATCLR)
OR
VLQINT
(ARM INT31)
Transmit serial
interrupt packet
For additional flexibility of interrupt handling, there is an interrupt priority vector status/clear register
(INTPRI) that reports the highest priority interrupt asserted in the VLYNQ interrupt pending/set register
(INTPENDSET) when INTLOCAL = 1. VLYNQ interprets bit 0 as the highest priority and it interprets bit 31
as the lowest priority. The value that is returned when read is the vector of the highest priority interrupt.
Software can clear that interrupt by writing back the vector value. Additionally, INTRPRI provides a
read-only status bit (NOINTPEND) to indicate whether or not there are any pending interrupts in the
interrupt status/clear register (INTSTATCLR).
2.12.2 Writes to Interrupt Pending/Set Register
As previously discussed, if the ARM CPU writes to the VLYNQ interrupt pending/set register
(INTPENDSET), then depending on the value of the INTLOCAL bit in the VLYNQ control (CTRL) register,
this will result in a local interrupt (to the device interrupt controller) or an interrupt packet transmitted over
the serial interface to the remote device.
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2.12.3 Remote Interrupts
Remote interrupts occur when an interrupt packet is received over the serial interface from a remote
device. The interrupt status is extracted from the packet and written to a location pointed to by the
interrupt pointer register (INTPTR).
The INTPTR should contain the address of the interrupt pending/set register (INTPENDSET). To get
INTPTR to contain the address of INTPENDSET, program INTPTR with a value of 14h (the offset for
INTPENDSET). Additionally, the INT2CFG bit in the VLYNQ control register (CTRL) must be set to 1,
dictating that the VLYNQ writes to a local register space (in this case, INTPENDSET).
Once an interrupt packet is received over the serial interface, the interrupt status is extracted and written
to INTPENDSET. After the interrupt status is extracted and written to INTPENDSET, the interrupt
The following summarizes the steps that are required to ensure that the device receives the remote
interrupts:
•
Program the VLYNQ interrupt pointer register (INTRPTR) with a value of 14h, which is the offset
address of the VLYNQ interrupt/pending set register (INTPENDSET).
•
Set the INT2CFG bit to 1 in the VLYNQ control register (CTRL).
2.12.4 Serial Bus Error Interrupts
Due to erroneous transmit packets that are detected by remote devices (remote error) or errors in the
inbound packets (local error), the serial bus errors result in the setting of the RERROR or LERROR bits in
the VLYNQ status register (STAT).
Additionally, if the INTENABLE bit is set in the VLYNQ control register (CTRL), setting the RERROR or
LERROR bits cause these status interrupts to post to the interrupt pending/set register (INTPENDSET),
causing the VLYNQINT to be asserted to the ARM CPU.
To ensure that serial bus errors result in interrupts to notify the application software, you must perform the
following steps:
1. Set the INTENABLE bit to 1 in the VLYNQ control register (CTRL).
2. Set the INTVEC bits in CTRL to point to a free bit in the VLYNQ interrupt pending/set register
(INTPENDSET). The serial bus error should result in setting the bits in INTPENDSET that are not used
by the application software for other interrupts (bit locations written directly in INTPENDSET or via
remote interrupts).
3. During VLYNQ initialization, the RERROR bit is set after the VLYNQ module achieves a link. When the
link bit is set in the VLYNQ status register (STAT), write a 1 to the RERROR bit. Writing a 1 to the
RERROR bit clears the RERROR bit and prevents the software interrupt handler from seeing the first
RERROR as a legitimate serial bus error interrupt.
2.13 DMA Event Support
The VLYNQ module on the DM644x device is classified as a master peripheral. Classification as a master
peripheral normally implies that the peripheral is able to sustain its own transfers without relying on any
external peripherals (for example, the system DMA, etc). However, the VLYNQ module does not have an
internal DMA (as some other master peripherals).
Therefore, it is likely that the VLYNQ module can rely on the on-chip enhanced DMA (EDMA3) controller
for performing burst transfer. The EDMA3 can still be used to perform burst transfers out to remote
VLYNQ memory map (writes). This use model provides better throughput with less overhead.
Note: There is no VLYNQ event that allows hardware synchronization to occur with the EDMA3
controller on the DM644x device.
The VLYNQ module uses a 16-word deep FIFO to buffer the burst writes. Since the EDMA3 controller is
much faster compared to the serial VLYNQ interface, a data back-up can occur. Therefore, configuring
EDMA3 for optimal transfer size, etc. is essential.
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Peripheral Architecture
2.14 Power Management
The VLYNQ module can be placed in reduced-power modes to conserve power during periods of low
activity. The power management of the peripheral is controlled by the processor Power and Sleep
Controller (PSC). The PSC acts as a master controller for power management of all of the peripherals on
the processor.
The power conservation modes that are available via the PSC are:
•
•
Idle/Disabled state : Idle/disabled state stops the clocks from going to the peripheral and prevents all of
the register accesses. After re-enabling the peripheral from its idle state, all registers prior to setting in
the disabled state are restored and data transmission proceeds. Re-initialization is not required.
Synchronized reset : The synchronized reset state is similar to the power-on reset (POR) state. When
the processor is turned on, reset to the peripheral is asserted, then clocks to the peripheral are gated.
Registers reset to their default values. When powering-up after a synchronized reset, all of the VLYNQ
module registers must be reconfigured and the link must be re-established before data transmission.
For more detailed information on power management procedures using the PSC, see the
TMS320DM644x DMSoC ARM Subsystem Reference Guide (SPRUE14).
If the serial clock is internally sourced, you can use the CLKDIV bit in the VLYNQ control register (CTRL)
to divide the serial clock down. This saves normal mode operation power consumption (at the expense of
reduced performance).
Additionally, the module provides the capability of auto-idling the serial clock domain (disable the VLYNQ
CLK) when the serial clock is sourced from the DM644x device and the VLYNQ SCRUN pin is connected
to the remote device. This allows power savings when there is no activity on the serial interface.
Note: There is no support for external wake-up for the VLYNQ module on the DM644x device. If
the VLYNQ module on the DM644x device has been disabled via the PSC, then even though
serial activity requests can be indicated from the remote VLYNQ device via the VLYNQ
SCRUN pin, it does not allow the serial clock (VLYNQ CLK) to be sourced until the VLYNQ
module is re-enabled via the PSC.
This can be configured by enabling the power management enable (PMEN) bit in the VLYNQ control
registers (CTRL, 0 = disable, 1 = enable) . This bit should only be set if the SCRUN pin is connected to
the remote VLYNQ device.
The SCRUN pin is a bi-directional pin which is driven low whenever there is serial activity on the local or
remote VLYNQ interface.
2.15 Emulation Considerations
During debug, the ARM CPU may be halted for single stepping, bench marking, profiling, or other debug
uses using the emulator. VLYNQ does not support emulation halts/suspend operation. VLYNQ operations
continue during emulation halt/suspend.
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VLYNQ Port Registers
3
VLYNQ Port Registers
Table 5. VLYNQ Register Address Space
Block Name
Start Address
01E0 1000h
01E0 1200h
0C00 0000h
End Address
01E0 11FFh
01E0 1FFFh
0CFF FFFFh
Size
VLYNQ Control Registers
Reserved
512 bytes
-
VLYNQ Remote Memory Map
64 Mbytes
Table 6 lists the memory-mapped registers for the VLYNQ port controller. See the device-specific data
manual for the memory address of these registers.
The first 128 bytes map to the VLYNQ configuration registers that are maintained by the local (device)
VLYNQ register control module while the second 128 bytes map to the remote configuration registers that
are physically located in the remote device linked by the VLYNQ serial interface. Any access to the
second set of registers causes VLYNQ to issue a read or write VLYNQ packet to be transmitted and only
completes if a link is established between the two devices.
Table 6. VLYNQ Port Controller Registers
Offset
0h
Acronym
REVID
Register Description
Section
Revision Register
Section 3.1
Section 3.2
Section 3.3
Section 3.4
Section 3.5
Section 3.6
Section 3.7
Section 3.8
Section 3.9
Section 3.10
Section 3.11
Section 3.12
Section 3.13
Section 3.14
Section 3.15
Section 3.16
Section 3.17
Section 3.18
4h
CTRL
Control Register
8h
STAT
Status Register
Ch
INTPRI
Interrupt Priority Vector Status/Clear Register
Interrupt Status/Clear Register
Interrupt Pending/Set Register
Interrupt Pointer Register
10h
14h
18h
1Ch
20h
24h
28h
2Ch
30h
34h
38h
3Ch
40h
44h
INTSTATCLR
INTPENDSET
INTPTR
XAM
Transmit Address Map Register
Receive Address Map Size 1 Register
Receive Address Map Offset 1 Register
Receive Address Map Size 2 Register
Receive Address Map Offset 2 Register
Receive Address Map Size 3 Register
Receive Address Map Offset 3 Register
Receive Address Map Size 4 Register
Receive Address Map Offset 4 Register
Chip Version Register
RAMS1
RAMO1
RAMS2
RAMO2
RAMS3
RAMO3
RAMS4
RAMO4
CHIPVER
AUTNGO
Auto Negotiation Register
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3.1 Revision Register (REVID)
The revision register (REVID) contains the major and minor revisions for the VLYNQ module. The REVID
Figure 9. Revision Register (REVID)
31
15
16
ID
R-1h
8
7
0
REVMAJ
R-2h
REVMIN
R-6h
LEGEND: R = Read only; -n = value after reset
Table 7. Revision Register (REVID) Field Descriptions
Bit
Field
Value
01h
Description
31-16 ID
Unique module ID.
Major revision.
15-8
7-0
REVMAJ
0-FFh
2h
Current major revision.
Minor revision.
REVMIN
0-FFh
6h
Current minor revision.
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3.2 Control Register (CTRL)
The control register (CTRL) determines operation of the VLYNQ module. The CTRL is shown in Figure 10
Figure 10. Control Register (CTRL)
31
30
29 27 26
RXSAMPELVAL
R/W- 3h
12
24
23
22
21
20 19 18
16
PMEN
R/W- 0
SCLKPUDIS Reserved
RTMVALIDWR RTMENABLE TXFASTPATH Reserved
CLKDIV
R/W- 0
R/W- 0
14
R-0
13
R/W- 0
8
R/W- 0
6
R/W- 0
R-0
15
7
3
2
1
0
CLKDIR
R/W- 0
INTLOCAL INTENABLE
R/W- 0 R/W- 0
INTVEC
R/W-0
INT2CFG
R/W-0
Reserved
R-0
AOPTDISABLE
R/W- 0
ILOOP RESET
R/W- 0 R/W- 0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 8. Control Register (CTRL) Field Descriptions
Bit
Field
Value Description
Power management enable.
31
PMEN
0
VLYNQ CLK is always active if it is set as an output (assuming that VLYNQ module is enabled).
If set as an output, VLYNQ CLK becomes inactive when there is no traffic over the serial bus.
1
The PMEN bit should only be set to 1 when the SCRUN is connected to the remote/external
VLYNQ device.
30
SCLKPUDIS
0
0
Serial clock pull-up disable. Always write 0.
29-27 Reserved
Reserved. Always read as 0. Writes have no effect.
26-24 RXSAMPELVAL
0-7h
RTM sample value. If the RTMENABLE bit is 0, the receive timing manager forces the value in the
RXSAMPELVAL bit as the clock sample value. If the RTMENABLE bit is 1, then the value set by
the RXSAMPELVAL bit is ignored. In order to modify the value, you must simultaneously write a 1
to the RTMVALIDWR bit.
23
22
RTMVALIDWR
RTMENABLE
RTM valid write bit.
0
1
Will not allow writes to RXSAMPLEVAL bits.
Will allow writes to RXSAMPLEVAL bits.
RTM enable bit.
The receive timing manager uses the value set in the RXSAMPLEVAL bit as the clock sample
value.
0
1
0-1
0
The receive timing manager is enabled. It automatically selects the receive clock.
Transmit fast path. When set, the fastest path is chosen for the serial data.
Reserved. Always read as 0. Writes have no effect.
21
TXFASTPATH
20-19 Reserved
18-16 CLKDIV
0-7h
Serial clock output divider.
15
CLKDIR
Serial CLK direction. Determines whether the VLYNQ CLK is an input or an output.
The VLYNQ CLK is externally sourced.
0
1
The VLYNQ CLK is internally sourced and equal to the VLYNQ module system clock divided by the
divider value set in the CLKDIV bit.
14
INTLOCAL
Interrupt local.
0
1
The interrupt is forwarded to the remote VLYNQ device over the serial interface as an interrupt
packet.
Interrupt is posted in the interrupt status/clear register and results in the assertion of the VLQINT to
the device interrupt controllers.
13
INTENABLE
INTVEC
Interrupt enable.
0
1
VLYNQ module status interrupts are ignored.
VLYNQ module status interrupts (if RERROR or LERROR bits are set) are posted to the interrupt
pending/set register.
12-8
0-1Fh Interrupt vector. This bit indicates which bit in the interrupt pending/set register is set for VLYNQ
module status (RERROR/LERROR) interrupts.
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Table 8. Control Register (CTRL) Field Descriptions (continued)
Bit
Field
Value Description
7
INT2CFG
Interrupt to configuration register. Determines which register is written with the status contained in
interrupt packets that are received over the serial interface. Always write 1 to this bit and configure
the interrupt pointer register to point to the interrupt pending/set register.
0
1
Bits[31:2] of the interrupt pointer register are used to point to a system interrupt register.
The least significant 8 bits of the interrupt pointer register are used to point to a VLYNQ module
local register (typically the interrupt pending/set register).
6-3
2
Reserved
0
Reserved. Always read as 0. Writes have no effect.
Address optimization disable.
AOPTDISABLE
0
1
Address optimization is enabled, eliminating unnecessary address bytes.
Address optimization is disabled.
1
0
ILOOP
RESET
Internal loop back.
0
1
Normal operation.
Serial transmit data is wrapped back to the serial receive data.
Software reset. It does not reset the VLYNQ MMR registers (except for the VLYNQ status register).
You have to reprogram the VLYNQ MMRs if they must have a different value after a software reset.
0
1
Normal operation.
All internal state machines are reset, the serial interface is disabled, and the link is lost.
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3.3 Status Register (STAT)
The status register (STAT) is used to detect conditions that may be of interest to the system designer. The
Figure 11. Status Register (STAT)
31
28
27
24
23
20
19
15
Reserved
R-0
SWIDTHIN
R-0
SWIDTHOUT
R-0
Reserved
R-0
14
7
12
4
11
10
9
8
RXCURRENTSAMPLE
R-0
RTM
R-1
IFLOW
R-0
OFLOW
R-0
RERROR
W1C-0
6
5
3
2
1
0
LERROR
W1C-0
NFEMPTY3
R-0
NFEMPTY2
R-0
NFEMPTY1
R-0
NFEMPTY0
R-0
SPEND
R-0
MPEND
R-0
LINK
R-0
LEGEND: R/W = Read/Write; R = Read only; W1C = Write 1 to clear bit; -n = value after reset; x= reset value is indeterminate
Table 9. Status Register (STAT) Field Descriptions
Bit
Field
Value Description
31-28 Reserved
27-24 SWIDTHIN
0
Reserved. Always read as 0. Writes have no effect.
Size of the inbound serial data. Indicates the number of receive pins that are being used to
establish the serial interface.
0-Fh
0
No pins used
1h
2h
3h
4h
1 RX pin used
2 RX pins used
3 RX pins used
4 RX pins used
5h-Fh Reserved
23-20 SWIDTHOUT
0-Fh
Size of the outbound serial data. Indicates the number of transmit pins that are being used
to establish the serial interface.
0
No pins used
1h
2h
3h
4h
1 TX pin used
2 TX pins used
3 TX pins used
4 TX pins used
5h-Fh Reserved
19-15 Reserved
0
0-Fh
1
Reserved. Always read as 0. Writes have no effect.
14-12 RXCURRENTSAMPLE
Current RTM sample. Indicates the current clock sample value used by RTM.
11
RTM
RTM enable. Always read as 1. Indicates that the VLYNQ module on the DM644x DMSoC
has the receive timing manager (RTM).
10
IFLOW
Inbound flow control.
Free to transmit.
0
1
Indicates that a flow control enable request has been received and has stalled transmit until
a flow control disable request is received.
9
OFLOW
Outbound flow control. Indicates the status of the two inbound FIFOs (FIFO1 or FIFO2).
Indicates that the internal flow control threshold is not yet reached.
0
1
Indicates that the internal flow control threshold has been reached (FIFO1 or FIFO2 is full)
and a flow control enable request has been sent to the remote device.
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Table 9. Status Register (STAT) Field Descriptions (continued)
Bit
Field
Value Description
8
RERROR
Remote Error. Write a 1 to this bit to clear it.
0
1
No error
This bit indicates that a downstream VLYNQ module has detected a packet error. This bit is
If this bit is set, and the INTENABLE (bit 13 in VLYNQ control register) is also set, it asserts
the VLYNQ interrupt (VLQINT).
7
LERROR
Local error. Write a 1 to this bit to clear it.
No error.
0
1
This bit indicates that an inbound packet contains an error that is detected by the local
VLYNQ module.
If this bit is set, and the INTENABLE (bit 13 in VLYNQ control register) is also set, it asserts
the VLYNQ interrupt (VLQINT).
6
5
4
3
2
NFEMPTY3
NFEMPTY2
NFEMPTY1
NFEMPTY0
SPEND
FIFO 3 is not empty.
0
1
Indicates that the slave command FIFO is empty.
Indicates that the slave command FIFO is not empty.
FIFO 2 is not empty.
0
1
Indicates that the slave data FIFO is empty.
Indicates that the slave data FIFO is not empty.
FIFO 1 is not empty.
0
1
Indicates that the master command FIFO is empty.
Indicates that the master command FIFO is not empty.
FIFO 0 is not empty.
0
1
Indicates that the master data FIFO is empty.
Indicates that the master data FIFO is not empty.
Pending slave request.
0
1
No pending slave requests.
Indicates detection of a transfer request initiated by the VLYNQ module to the off-chip
peripheral (TX slave configuration bus interface).
1
0
MPEND
LINK
Pending master requests.
0
1
No pending master requests.
Indicates detection of a transfer request initiated by an off-chip peripheral to the VLYNQ
module (RX master configuration bus interface).
Link
0
1
Indicates that the serial interface initialization sequence has not yet completed or the link
has timed out.
Indicates that the serial interface initialization sequence has completed successfully.
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3.4 Interrupt Priority Vector Status/Clear Register (INTPRI)
The interrupt priority vector status/clear register (INTPRI) displays the highest priority vector with a
pending interrupt when read. When writing, only bits [4:0] are valid, and the value represents the vector of
Figure 12. Interrupt Priority Vector Status/Clear Register (INTPRI)
31
30
16
0
NOINTPEND
R-1h
Reserved
R-0
15
5
4
Reserved
R-0
INSTAT
R/W-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 10. Interrupt Priority Vector Status/Clear Register (INTPRI) Field Descriptions
Bit
Field
Value Description
31
NOINTPEND
Interrupt pending status.
0
1
0
Indicates there is a pending interrupt.
Indicates that there are no pending interrupts from the interrupt status/clear register.
Reserved. Always read as 0. Writes have no effect.
30-5
4-0
Reserved
INSTAT
When read, this field displays the vector that is mapped to the highest priority interrupt bit that is
0-1Fh pending from the interrupt status/clear register, with bit 0 as the highest priority, and bit 31 as the
lowest. Writing the vector value back to this field clears the interrupt.
3.5 Interrupt Status/Clear Register (INTSTATCLR)
The interrupt status/clear register (INTSTATCLR) indicates the unmasked interrupt status. The
Figure 13. Interrupt Status/Clear Register (INTSTATCLR)
31
0
INTCLR
R/W-0
LEGEND: R/W = Read/Write; -n = value after reset
Table 11. Interrupt Status/Clear Register (INTSTATCLR) Field Descriptions
Bit
Field
Value
Description
31-0
INTCLR
0-FFFF FFFFh This field indicates the unmasked status of each interrupt. Writing a 1 to any set bit in this field
clears the corresponding interrupt. If there is a bit set in this register and if the INTLOCAL bit in
the control register (CTRL) is also set, the VLYNQ interrupt (VLQINT) is asserted.
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3.6 Interrupt Pending/Set Register (INTPENDSET)
The interrupt pending/set register (INTPENDSET) indicates the pending interrupt status when the
INTLOCAL bit in the control register (CTRL) is not set. When the interrupt packet is forwarded on the
Figure 14. Interrupt Pending/Set Register (INTPENDSET)
31
0
INTSET
R/W-0
LEGEND: R/W = Read/Write; -n = value after reset
Table 12. Interrupt Pending/Set Register (INTPENDSET) Field Descriptions
Bit
Field
Value
Description
31-0
INTSET
0-FFFF FFFFh This field indicates the unmasked status of each pending interrupt.
0
1
Writing a 0 has no effect.
Writing a 1 to any bit:
if INTLOCAL = 0 in CTRL, interrupt packet is sent on the serial interface.
If INTLOCAL = 1 in CTRL, VLYNQ module interrupt (VLQINT) is asserted.
3.7 Interrupt Pointer Register (INTPTR)
The interrupt pointer register (INTPTR) typically contains the address of the interrupt pending/set register
(INTPENDSET) within the VLYNQ module. To program INTPTR to point to INTPENDSET, program a
value of 14h (the offset of INTPENDSET). Additionally, the INT2CFG bit in the control register (CTRL)
Figure 15. Interrupt Pointer Register (INTPTR)
31
2
1
0
INTPTR
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 13. Interrupt Pointer Register (INTPTR) Field Descriptions
Bit
Field
Value
Description
31-2
INTPTR
0-3FFF FFFFh
Interrupt pointer. Program this register with the address of the interrupt pending/set register
(14h).
1-0
Reserved
0
Reserved. Always read as 0. Writes have no effect.
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3.8 Transmit Address Map Register (XAM)
The transmit address map register (XAM) is used to translate transmit packet addresses to remote device
Figure 16. Transmit Address Map Register (XAM)
31
2
1
0
TXADRMAP
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 14. Address Map Register (XAM) Field Descriptions
Bit
Field
Value
Description
31-2
TXADRMAP
0-3FFF FFFFh This field is subtracted from the slave configuration bus address [25:0] to obtain the zero
relative transmit packet address. This field should be programmed with a value of 0 (reset
value).
1-0
Reserved
0
Reserved. Always read as 0. Writes have no effect.
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3.9 Receive Address Map Size 1 Register (RAMS1)
The receive address map size 1 register (RAMS1) is used to identify the intended destination of inbound
Figure 17. Receive Address Map Size 1 Register (RAMS1)
31
2
1
0
RXADRSIZE1
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 15. Receive Address Map Size 1 Register (RAMS1) Field Descriptions
Bit
Field
Value
Description
31-2
RXADRSIZE1
0-3FFF FFFFh The RXADRSIZE1 field is used to determine if receive packets are destined for the first of
four mapped address regions. RXADRSIZE1 is compared with the address contained in the
receive packet. If the received packet address is less than the value in RXADRSIZE1, the
packet address is added to the receive address map offset 1 register (RAMO1) to obtain the
translated address.
1-0
Reserved
0
Reserved. Always read as 0. Writes have no effect.
3.10 Receive Address Map Offset 1 Register (RAMO1)
The receive address map offset 1 register (RAMO1) is used with the receive address map size 1 register
(RAMS1) to translate receive packet addresses to local device configuration bus addresses. The RAMO1
Figure 18. Receive Address Map Offset 1 Register (RAMO1)
31
2
1
0
RXADROFFSET1
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 16. Receive Address Map Offset 1 Register (RAMO1) Field Descriptions
Bit
Field
Value
Description
31-2 RXADROFFSET1
0-3FFF FFFFh The RXADROFFSET1 field is used with the receive address map size 1 register (RAMS1)
to determine the translated address for serial data. If the received packet address is less
than the value in RAMS1, the packet address is added to the contents of this register to
obtain the translated address.
1-0
Reserved
0
Reserved. Always read as 0. Writes have no effect.
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3.11 Receive Address Map Size 2 Register (RAMS2)
The receive address map size 2 register (RAMS2) is used to identify the intended destination of inbound
Figure 19. Receive Address Map Size 2 Register (RAMS2)
31
2
1
0
RXADRSIZE2
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 17. Receive Address Map Size 2 Register (RAMS2) Field Descriptions
Bit
Field
Value
Description
31-2
RXADRSIZE2
0-3FFF FFFFh The RXADRSIZE2 field is used to determine if receive packets are destined for the second
of four mapped address regions. RXADRSIZE2 is compared with the address contained in
the receive packet. If the received packet address is less than the value in RXADRSIZE2,
the packet address is added to the receive address map offset 2 register (RAMO2) to obtain
the translated address.
1-0
Reserved
0
Reserved. Always read as 0. Writes have no effect.
3.12 Receive Address Map Offset 2 Register (RAMO2)
The receive address map offset 2 register (RAMO2) is used with the receive address map size 2 register
(RAMS2) to translate receive packet addresses to local device configuration bus addresses. The RAMO2
Figure 20. Receive Address Map Offset 2 Register (RAMO2)
31
2
1
0
RXADROFFSET2
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 18. Receive Address Map Offset 2 Register (RAMO2) Field Descriptions
Bit
Field
Value
Description
31-2 RXADROFFSET2
0-3FFF FFFFh The RXADROFFSET2 field is used with the receive address map size 2 register (RAMS2)
to determine the translated address for serial data. If the received packet address is less
than the value in RAMS2, the packet address is added to the contents of this register to
obtain the translated address.
1-0
Reserved
0
Reserved. Always read as 0. Writes have no affect.
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3.13 Receive Address Map Size 3 Register (RAMS3)
The receive address map size 3 register (RAMS3) is used to identify the intended destination of inbound
Figure 21. Receive Address Map Size 3 Register (RAMS3)
31
2
1
0
RXADRSIZE3
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 19. Receive Address Map Size 3 Register (RAMS3) Field Descriptions
Bit
Field
Value
Description
31-2
RXADRSIZE3
0-3FFF FFFFh The RXADRSIZE3 field is used to determine if receive packets are destined for the third of
four mapped address regions. RXADRSIZE3 is compared with the address contained in the
receive packet. If the receive packet address is less than the value in RXADRSIZE3, the
packet address is added to the receive address map offset 3 register (RAMO3) to obtain the
translated address.
1-0
Reserved
0
Reserved. Always read as 0. Writes have no effect.
3.14 Receive Address Map Offset 3 Register (RAMO3)
The receive address map offset 3 register (RAMO3) is used with the receive address map size 3 register
(RAMS3) to translate receive packet addresses to local device configuration bus addresses. The RAMO3
Figure 22. Receive Address Map Offset 3 Register (RAMO3)
31
2
1
0
RXADROFFSET3
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 20. Receive Address Map Offset 3 Register (RAMO3) Field Descriptions
Bit
Field
Value
Description
31-2 RXADROFFSET3
0-3FFF FFFFh The RXADROFFSET3 field is used with the receive address map size 3 register (RAMS3)
to determine the translated address for serial data. If the receive packet address is less
than the value in RAMS3, the packet address is added to the contents of this register to
obtain the translated address.
1-0
Reserved
0
Reserved. Always read as 0. Writes have no effect.
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3.15 Receive Address Map Size 4 Register (RAMS4)
The receive address map size 4 register (RAMS4) is used to identify the intended destination of inbound
Figure 23. Receive Address Map Size 4 Register (RAMS4)
31
2
1
0
RXADRSIZE4
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 21. Receive Address Map Size 4 Register (RAMS4) Field Descriptions
Bit
Field
Value
Description
31-2
RXADRSIZE4
0-3FFF FFFFh The RXADRSIZE4 field is used to determine if receive packets are destined for the fourth of
four mapped address regions. RXADRSIZE4 is compared with the address contained in the
receive packet. If the receive packet address is less than the value in RXADRSIZE4, the
packet address is added to the receive address map offset 4 register (RAMO4) to obtain the
translated address.
1-0
Reserved
0
Reserved. Always read as 0. Writes have no effect.
3.16 Receive Address Map Offset 4 Register (RAMO4)
The receive address map offset 4 register (RAMO4) is used with the receive address map size 4 register
(RAMS4) to translate receive packet addresses to local device configuration bus addresses. The RAMS4
Figure 24. Receive Address Map Offset 4 Register (RAMO4)
31
2
1
0
RXADROFFSET4
R/W-0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 22. Receive Address Map Offset 4 Register (RAMO4) Field Descriptions
Bit
Field
Value
Description
31-2 RXADROFFSET4
0-3FFF FFFFh The RXADROFFSET4 field is used with the receive address map size 4 register (RAMS4)
to determine the translated address for serial data. If the receive packet address is less
than the value in RAMS4, the packet address is added to the contents of this register to
obtain the translated address.
1-0
Reserved
0
Reserved. Always read as 0. Writes have no effect.
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3.17 Chip Version Register (CHIPVER)
VLYNQ allows inter-connection of many VLYNQ devices. In order for software to control the device
functions, there must be a mechanism that allows the software to identify VLYNQ devices. Each device
that has a VLYNQ module in it has a unique device ID associated with it, which is software readable via a
memory-mapped register within the VLYNQ module called the chip version register (CHIPVER). This is
also useful in communicating with remote devices, as the local VLYNQ device register map contains a
copy of the remote device's registers as well. This allows the software to determine the remote chip ID
and, hence, determine the remote memory-map without trying to access random remote addresses to find
Figure 25. Chip Version Register (CHIPVER)
31
15
16
DEVREV
R-0
0
DEVID
R-25h
LEGEND: R = Read only; -n = value after reset
Table 23. Chip Version Register (CHIPVER) Field Descriptions
Bit
31-16 DEVREV
15-0 DEVID
Field
Value
0-FFFFh
0-FFFFh
25h
Description
Device revision. This field reflects the value of the device revision pins.
Device ID.
DM644x device ID.
3.18 Auto Negotiation Register (AUTNGO)
The auto negotiation register (AUTNGO) reflects the ability of the VLYNQ module residing in the device to
communicate with the remote VLYNQ device on their respective abilities after reset. The AUTNGO is
Figure 26. Auto Negotiation Register (AUTNGO)
31
17
16
2X
Reserved
R-0
R-0
15
0
Reserved
R-0
LEGEND: R/W = Read/Write; R = Read only; -n = value after reset
Table 24. Auto Negotiation Register (AUTNGO) Field Descriptions
Bit
Field
Value Description
31-17 Reserved
0
Reserved. Always read as 0. Writes have no effect.
Version 2.x mode.
16
2X
0
1
0
Indicates that a link was established with a remote device that has a version 1.x VLYNQ module in it.
Indicates that a link was established with a remote device that has a version 2.x VLYNQ module in it.
Reserved. Always read as 0. Writes have no effect.
15-0
Reserved
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Remote Configuration Registers
4
Remote Configuration Registers
The remote configuration registers listed in Table 25 are the same registers as previously described, but
they are for the remote VLYNQ device.
Note: Before attempting to access the remote registers (offsets 80h through C0h) , you must
ensure that a link is established with the remote device. Poll the LINK bit in the VLYNQ
status register (STAT) to do this.
It is not necessary to configure the address translation registers to access the remote
device's memory-mapped registers after the link has been established.
Depending on the version and chip specific implementation, the VLYNQ module on the
remote device might have additional registers or different reset values. Refer to the remote
device data sheet for a precise description of the VLYNQ registers that exist in the remote
device.
Table 25. VLYNQ Port Remote Controller Registers
Offset
80h
84h
88h
8Ch
90h
94h
98h
9Ch
A0h
A4h
A8h
ACh
B0h
B4h
B8h
BCh
C0h
C4h
C8h
CCh
E0h
E4h
Acronym
RREVID
Register Description
Remote Revision Register
RCTRL
Remote Control Register
RSTAT
Remote Status Register
RINTPRI
Remote Interrupt Priority Vector Status/Clear Register
Remote Interrupt Status/Clear Register
Remote Interrupt Pending/Set Register
Remote Interrupt Pointer Register
RINTSTATCLR
RINTPENDSET
RINTPTR
RXAM
Remote Transmit Address Map Register
Remote Receive Address Map Size 1 Register
Remote Receive Address Map Offset 1 Register
Remote Receive Address Map Size 2 Register
Remote Receive Address Map Offset 2 Register
Remote Receive Address Map Size 3 Register
Remote Receive Address Map Offset 3 Register
Remote Receive Address Map Size 4 Register
Remote Receive Address Map Offset 4 Register
Remote Chip Version Register
RRAMS1
RRAMO1
RRAMS2
RRAMO2
RRAMS3
RRAMO3
RRAMS4
RRAMO4
RCHIPVER
RAUTNGO
RMANNGO
RNGOSTAT
RINTVEC0
RINTVEC1
Remote Auto Negotiation Register
Remote Manual Negotiation Register
Remote Negotiation Status Register
Remote Interrupt Vector 3-0 Register
Remote Interrupt Vector 7-4 Register
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Appendix A
Appendix A VLYNQ Protocol Specifications
VLYNQ relies on 8b/10b block coding to minimize the number of serial pins and allow for in-band
packet delineation and control. The following sections include general 8b/10b coding definitions and
their implementation.
A.1 Special 8b/10b Code Groups
Table A-1. Special 8b/10b Code Groups
Code Group Name
K28.0
Octet Value
Octet Bits
0001 1100
0011 1100
0101 1100
0111 1100
1001 1100
1011 1100
1101 1100
1111 1100
1111 0111
1111 1011
1111 1101
1111 1110
Current RD -
001111 0100
001111 1001
001111 0101
001111 0011
001111 0010
001111 1010
001111 0110
001111 1000
111010 1000
110110 1000
101110 1000
011110 1000
Current RD +
110000 1011
110000 0110
110000 1010
110000 1100
110000 1101
110000 0101
110000 1001
110000 0111
000101 0111
001001 0111
010001 0111
100001 0111
1C
3C
5C
7C
9C
BC
DC
FC
F7
K28.1
K28.2
K28.3
K28.4
K28.5
K28.6
K28.7
K23.7
K27.7
FB
FD
FE
K29.7
K30.7
A.2 Supported Ordered Sets
Each VLYNQ module must support a limited number of ordered sets. Ordered sets provide for the
delineation of packets and synchronization between VLYNQ modules at opposite ends of the serial
connection. VLYNQ 2.0 and later versions do not require some of the following ordered sets.
Table A-2. Supported Ordered Sets
Code
/I/
Ordered Set
Idle
Encoding
/K28.5/
/K29.7/
/K23.7/
/K28.0/
/K28.2/
/K28.1/
/K28.4/
/K28.6/
/K30.7/
Octet Value
BC
FD
F7
IC
/T/
/M/
/P/
/C/
/E/
/0/
End of Packet
Byte Disable
Flow Control Enable
Flow Control Disable
Error Indication
Init0
5C
3C
9C
DC
FE
/I/
Init1
/L/
Link
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VLYNQ 2.0 Packet Format
A.2.1
Idle (/I/)
The idle ordered sets are transmitted continuously and repetitively whenever the serial interface is idle.
Idle is also used in the place of the flowed code in VLYNQ versions 2.0 and later.
A.2.2
A.2.3
A.2.4
End of Packet (/T/)
An end of packet delimiter delineates the ending boundary of a packet.
Byte Disable (/M/)
The byte disable symbol masks bytes for write operations.
Flow Control Enable (/P/)
A flow control enable request is transmitted when a VLYNQ module’s receive FIFO is full or nearly full.
This code causes the remote VLYNQ device to cease transmission of data.
A.2.5
A.2.6
A.2.7
A.2.8
A.2.9
Flow Control Disable (/C/)
The flow control disable request is transmitted by a VLYNQ module when RX FIFO resources are
available to accommodate additional data.
Error Indication (/E/)
The error indication is transmitted when errors are detected within a packet. Examples of such errors
include illegal packet types and code groups.
Init0 (/0/)
The Init0 code group is used during the link initialization sequence. VLYNQ 2.0 and later versions use this
code with an extra byte for identifying version 1.X devices.
Init1 (/1/)
The Init1code group is used during the Link initialization sequence. VLYNQ 2.0 and later uses this code
with an extra byte for identifying version 1.X devices.
Link (/L/)
The link code group is used during the link initialization sequence. A link code group is also transmitted
each time the internal link timer expires.
A.3 VLYNQ 2.0 Packet Format
Multi-byte fields are transferred least-significant byte first.
Figure A-1. Packet Format (10-bit Symbol Representation)
10 bits
cmd 1
10 bits
10 bits
<4*10 bits
N*10 bits
10 bits
eop
cmd 2
bytecnt
address
data
pkttype
adrmask
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VLYNQ 2.0 Packet Format
Table A-3. Packet Format (10-bit Symbol Representation) Description
Field
Value Description
PKTTYPE[3:0]
This field indicates the packet type.
0000 Reserved
0001 Write with address increment.
0010 Reserved
0011 Write 32-bit word with address increment.
0100 Reserved
0101 Configuration write with address increment.
0110 Reserved for extended command indicator (cmd2).
0111 Interrupt
1000 Reserved
1001 Read with address increment.
1010 Reserved
1011 Read 32-bit word with address increment.
1100 Reserved
1101 Configuration read with address increment.
1110 Reserved for VLYNQ version 2.0 and later.
1111 Read response for all VLYNQ versions.
ADRMASK[3:0]
BYTECNT[7:0]
Indicates which byte of the address is included in the packet. Only address bytes that have changed
since the previous address will be included. Each bit corresponds to one byte of address.
Byte count. This field indicates the total number of bytes in the packet. This field is only included for
write, read, and configuration packet types. All other packet types have fixed lengths and do not
require this field.
ADDRESS[7:0]
Address byte 0. This byte is included only if ADRMASK[0] is set to 1. If ADRMASK[0] is cleared to 0,
assume this byte is equal to bits 7:0 of the previous address. Read response packets do not include
this field.
ADDRESS[15:8]
ADDRESS[23:16]
ADDRESS[31:24]
Address byte 1. This byte is included only if ADRMASK[1] is set to 1. If ADRMASK[1] is cleared to 0,
assume this byte is equal to bits 15:8 of the previous address. Read response packets do not include
this field.
Address byte 2. This byte is only included if ADRMASK[2] is set to 1. If ADRMASK[2] is cleared to 0,
this assume this byte is equal to bits 23:16 of the previous address. Read response packets do not
include this field.
Address byte 3. This byte is only included if ADRMASK[3] is set to 1. If ADRMASK[3] is cleared to 0,
assume this byte is equal to bits 31:24 of the previous address. Read response packets do not
include this field.
DATA
EOP
Data payload. The maximum data payload size is limited to sixteen 32-bit words to allow it to fit in the
RX FIFO.
End of packet indicator, /T/.
The CMD2 bit is only included in the packet, if the packet type indicates extended command
(PKTTYPE = 0110).
Use configuration packet types to remotely access VLYNQ module registers. The configuration packet
types do not depend on control register bit settings.
42
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VLYNQ 2.X Packets
A.4 VLYNQ 2.X Packets
An example of what can happen to a write burst due to remote and local FIFO state changes and the link
pulse timer expiring is shown in Example A-1. This protocol can be extended to apply to multiple channels;
therefore, the data return channel is logically isolated from the command channel.
Example A-1. A write burst due to remote and local FIFO state changes and the link pulse timer
expiring
Basic packets:
Read32 - caaaaT
Write32 - caaaaddddT
ReadCfg - claaaaT
WriteCfg - claaaaddddddddT
ReadBurst - claaaaT
WriteBurst - claaaaddddddddddddT
Int - cddddT
ReadReturn - clddddddddT
Where
I - Idle
T - EndOfPacket
d - data
a - address
c - command
l
- length
M - Byte mask
I[#] - Flowed, # is used when exiting flowed for a channel, the # is actually the current
channel command.
P# - Flow Enable for a channel
C# - Flow Disable for a channel
L - Link pulse
and what is in italics is optional data up to 16 words total.
Packet with byte enables:
WriteBurst - claaaaMMddMMddMMddT
The above packet wrote to the LS half words from the specified address.
Packet that has been flowed due to remote FIFO status:
WriteBurst - claaaaMMddMIIIIIIIIIIIII#MddMMddT
The packet was extended using the I code. The # is used to
indicate that the same channel was continued.
To the same packet, the potential flowing of the local FIFO’s is added:
WriteBurst - claaaaMMddMIIP#IIIIIIIIIIIII#MddMMdC#dT
Link pulse to the stream is added:
WriteBurst - claaLaaMMddMIIP#IIIIIIIIIII#MddMMdC#dT
An example of a write burst flowed and interrupted by a read return data burst is shown below. In the
example, a 1 indicates a data return channel (it is actually the return data command) and a 0 indicates a
command channel, which is the command for the transaction.
IIIIclaaaaddddIcldddIII1ddddII0dddddddddddddIIIIII0dddTIIIII1dTIIII
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43
VLYNQ 2.X Packets
A command, length, address, and start receive data from the idle stream. A flow enable was received for
the command channel, but there is data to return, so the flow is followed by a channel 1 descriptor (the
command for return data actually indicates a channel 1), and the channel 1 packet is now under way. A
flow is now received for channel 1, but it is soon disabled so the channel 1 packet continues. The flow is
enabled for channel one again, quickly after flow is released for channel 0, so the data continues for
channel 0 when a flow is received again for channel 0. Channel 0 then receives a flow disable, completes
its packet, followed by channel 1 flow disable, where the channel 1 packet is also completed.
44
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Appendix B
Appendix B Write/Read Performance
The following sections discuss the write versus read performance and how the throughput (read or
write) should be calculated for a given data width and serial clock frequency.
Note: The data and throughput calculations shown here are sample calculations for most
ideal situations. In general, the data rates depend on a variety of other factors, such
as efficiency of read/write burst transactions, ability of buffering up read/write data,
and how best it can be serially shifted out without stalling additional read/write data
burst, remote and local components , both external and internal (device operations,
board considerations, etc.).
B.1 Write Performance
The max write rate describes the maximum available data rate of the serial interface for transmission,
taking into consideration the 8b/10b encoding overheads. This is calculated as follows:
Max write rate = VLYNQ Serial Clock (MHZ) × No. of Pins × 8b/10b encoding overhead
The 8b/10b encoding overhead essentially accounts for 20% overhead, thus the actual data throughput
after subtraction of the encoding overhead gives a factor of 0.8. For example, if the VLYNQ clock is
running at 99 MHZ on a 4 pin per direction interface, the raw data is 99 × 4 or 396 Mbps. After the 8B10B
encoding is removed, the maximum write rate is 396 × 0.8 = 316.8 Mbps.
The total throughput on the VLYNQ interface includes both transmit and receive directions. Therefore, for
the above configuration, a remote device can also be writing to the local device at the same data rates,
then the total throughput is the sum of transmit and receive rates, or 633.6 Mbps.
In addition to the 8b/10b encoding, the packet structure for read/write operations also results in additional
overheads. The VLYNQ module can transfer single 32-bit words or a burst of up to sixteen 32-bit words.
The packet structure of the writes is shown below, here each character represents a byte.
Write32 - caaaaddddT
WriteBurst - claaaaddddddddddddT
Where
T - EndOfPacket
d - data, dddd represents additional 32-bit words in burst, up to 16 words.
a - address
c - command
l
- length
The example above illustrates that single writes require 6 bytes of overhead, while burst writes require
8 bytes of overhead (due to the additional length of the field). From this, a scaling factor can be calculated
(data bytes/total bytes), as show in Table B-1. The actual throughput is then calculated as the [scaling
factor] × [max write rate].
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Write Performance
Table B-1. Scaling Factors
Burst Size in 32-bit words
Data Bytes
Overhead Bytes
Scaling Factor
1
4
4
6
40%
16
32
64
7
7
7
69.56%
82.05%
90.14%
8
16
Table B-2. Expected Throughput (VLYNQ Interface Running at 76.5 MHZ and 99 MHZ)
Interface Running at 76.5 MHZ
Interface Running at 99 MHZ
Burst Size in
32-bit Words
Number of VLYNQ Pins
Mbits/sec
24.19
Mbytes/sec
3.02
Mbits/sec
31.68
Mbytes/sec
3.96
1
1
4
42.07
5.26
55.09
6.89
8
49.62
6.20
64.98
8.12
16
1
54.52
6.81
71.39
8.92
2
3
4
48.38
6.05
63.36
7.92
4
84.14
10.52
12.41
13.63
9.07
110.18
129.97
142.78
95.04
13.77
16.25
17.85
11.88
20.66
24.37
26.77
15.84
27.55
32.49
35.70
8
99.25
16
1
109.03
72.58
4
126.21
148.87
163.55
96.77
15.78
18.61
20.44
12.10
21.03
24.81
27.26
165.27
194.95
214.17
126.72
220.37
259.93
285.56
8
16
1
4
168.28
198.50
218.07
8
16
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Read Performance
B.2 Read Performance
Since reads must complete a transmit-remote read-receive cycle before starting another read transaction,
the data throughput is lower as compared to writes. There is latency involved in reading the data from the
remote device; and in some cases, a local latency in writing the returned data before the next read can
start.
The max read rate is calculated the same way as the max write rate. The packet overhead is as shown
below:
Read32 - caaaaT
ReadBurst - claaaaT
ReadReturn - clddddddddT
Where
T - EndOfPacket
d - data, dddd represents additional 32-bit words in burst, up to 16 words.
a - address
c - command
l
- length
There are 6 bytes of overhead for a single read, 7 bytes for burst reads, and 3 bytes for read returns. The
time required for a read is the total of the time for the read request, remote latency, read return, and local
latency. Thus, the throughput can be calculated as data bytes/total transaction time, where the latency of
both local and remote devices is combined.
Read Throughput = data/ (((Read + ReadReturn + data)/max read rate) + Latency
= (data × max read rate)/((Read + ReadReturn + data) + Latency × max
read rate)
For example, with a 4 pin, 99 MHZ VLYNQ connection, for a single 32-bit word read:
Read Throughput = 32 bits × 316.8 Mbps/ (6 × 8 + 3 × 8 + 4 × 8 + Latency × 316.8Mbps)
= 10137.6/(104 + Latency × 316.8 Mbps)
Similarly, for a burst read of sixteen 32-bit words, with a 4 pin, 99 MHZ VLYNQ connection
Read Throughput = 16 × 32 bits × 316.8Mbps/(6 × 8 + 3 × 8 + 16 × 4 × 8 + Latency × 316.8Mbps)
= 162201.6/(584 + Latency × 316.8Mbps)
Using the formula above, the relative performance with various latencies is illustrated for a 4 pin, 99 MHZ
Table B-3. Relative Performance with Various Latencies
Number of VLYNQ Pins
(99 MHZ)
Throughput
(Mbits/sec)
Throughput
(Mbytes/sec)
Burst Size in 32-bit Words
Latency (μsec)
4
16
0
1
277.74
179.70
43.02
5.00
34.72
22.46
5.38
10
100
0.62
To efficiently use VLYNQ bandwidth, it is desirable for each VLYNQ device to write from the local device
to the remote device. Burst transactions are more efficient than single read/write transactions.
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Appendix C
Appendix C Revision History
Table C-1. Document Revision History
Reference
Additions/Modifications/Deletions
Section 2.9
Changed fourth paragraph.
Added NOTE.
Table 8
Section 3.17
Figure 25
Table 23
Changed Description of INTLOCAL.
Changed paragraph.
Changed DEVID reset value.
Changed DEVID Description.
Changed figure.
Figure A-1
Table A-3
Table B-2
Changed Description of PKTTYPE[3:0] = 0110.
Changed table.
Deleted Table B-3. Subsequent tables renumbered.
48
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