Versions Compared

Key

  • This line was added.
  • This line was removed.
  • Formatting was changed.
Comment: SpacewireTiming in test description

All the contents of this document are protected by the copyright law. They may not be disclosed to third parties or copied or duplicated in any form without consent of NanoXplore.

Introduction

Aim of document

This document is intended to guide users on Training Package testcases.

In order to be more familiar with the Training Package environment, please refer to TrainingPackage_UserManual. For any kind of help, please contact NanoXplore support team at support@nanoxplore.com.

Content

For each testcase of the Training Package, an application note informing about implemented NanoXplore python methods (cf Impulse User Manual) and NanoXplore primitives (cf https://nanoxplore-wiki.atlassian.net/wiki/spaces/SANDBOX/pages/202244165) is provided in this document.

Test plan

List of categories

Testcases are grouped by category depending on the aim of the testcase (python method, primitive, …).

...

  • Attribute: Attributes can be inserted in the design in order to add a constraint on a register, a memory, …

  • Board: Designs to program NanoXplore evaluation boards (DevKit / BringUp).

  • Component: Multiple configurations for NanoXplore primitives.

  • Design: Various types of designs without any specific IP.

  • Init: Memory initialization

  • Ip: Designs implementing NanoXplore Ips.

  • MappingDirective:Directive of elements mapping in NanoXplore primitives.

  • Pad: Pad configurations.

  • PlacingConstraint: Constraints for manual placing of NanoXplore primitives.

  • ProcessingSystem: Communication between Programmable Logic and Processing System.

  • StaConstraint: Constraintsfor static time analysis.


List of testcases

Hereafter the list of all available testcases for each category:

  • Attribute:

    • NxInit

    • NxPort

    • NxUse

    • SynKeep

    • SynPreserve

  • Board:

    • Scope

    • SwichBlink

    • ThermalSensor

  • Component

    • ClockSwitch

    • Ddfr

    • DspConfig

    • IoConfig

    • PllConfig

    • RamConfig

    • RfbConfig

    • Service

    • Soc

    • WfgConfig

  • Design

    • DelayIo

    • DspCascaded

    • DspMultAcc

    • DspTranspose

    • LowskewManagement

    • MemInfer

  • Init

    • Ram

  • Ip

    • CrossDomain

    • Ddr2Dfi

    • HsslEsistream

    • R5AxiMaster

    • R5AxiSlave

    • R5Jtag

    • Serdes

    • SpacewireLoopback

    • SpacewireRoadmap

    • SpacewireRx

  • MappingDirective

    • Adder

    • BlackBox

    • Memory

  • Pad

    • Parameter

    • Registered

  • PlacingConstraint

    • Aperture

    • ConstrainPath

    • ExportSites

    • Focus

    • Obstruction

    • PreplaceI

    • Region

    • RingLocation

    • Site

  • ProcessingSystem

    • Interruptions

    • Watchdog

    • SoC AXI test

  • StaConstraint

    • CaseAnalysis

    • ClockGroup

    • DelayPath

    • FalsePath

    • GeneratedClock

    • InputOutputDelay

    • ReportPath

    • SpacewireTiming

 


Testcase content

Each testcase of this application note contains the following fields:

  • Description: Global description of the aim of the testcase highlighting which method, primitive, IP, … is concerned and illustrated.

  • Environment: It informs about all possibilities that can be performed in that testcase in order to help the user to get examples.

Variant

All compliant variants from NanoXplore chips family

Embedded

Embedded variant compliance in case the testcase only needs the fabric

Simulation

Indicates whether a simulation environment is available or not on Modelsim

Attributes

All attributes implemented in the VHDL code

IP

All NanoXplore primitives, hard or soft IP implemented in the VHDL code

Methods

All NanoXplore python methods implemented in the python script

Table: Testcase example environment

  • Option: Project can be launched with or without an option when launching the python script in order to stress the difference if option is set or not. Please have a look at the https://nanoxplore-wiki.atlassian.net/wiki/spaces/SANDBOX/pages/202244782 for more information.

  • NanoXmap check: What the user can observe after launching the NanoXmap project.

  • Simulation check: What the user can observe after launching the Modelsim simulation in case of available simulation environment.

  • Board check: What the user can observe after programming the bitstream on an DevKit Evaluation Board.

Testcase Description

Attribute

NxInit

Description:

By using nx_init attribute, the user can initialize an inferred memory directly in the design code. It is an alternative way from using the addMemoryInitialization NXpython method in the python script. The syntax is the following one:

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

Yes

Attributes

nx_init

IP

 

Methods

 

Table: Attribute NxInit environment

...

Board check: No board purpose for this testcase.


 

NxPort

Description:

By using nx_port attribute, the user can add parameters to the design top IOs directly in the design code. It is an alternative way from using the addPad NXpython method in the python script. The syntax is the following one:

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

No

Attributes

nx_port

IP

 

Methods

 

Table: Attribute NxPort environment

...

Board check: No board purpose for this testcase.

 


NxUse

Description:

By using nx_use attribute, the user can add directive for inferred elements directly in the design code. It is an alternative way from using the addMappingDirective NXpython method in the python script. The syntax is the following one:

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

No

Attributes

nx_use

IP

 

Methods

 

Table: Attribute NxUse environment

...

Board check: No board purpose for this testcase.

 


SynKeep

Description:

By using syn_keep attribute, the user can avoid any optimization of a combinatorial signal directly in the design code. syn_keep attribute can be replaced by syn_noprune attribute with exactly the same impact. The syntax is the following one:

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

syn_keep syn_noprune

IP

 

Methods

 

Table: Attribute SynKeep environment

...

Board check: No board purpose for this testcase.

 


SynPreserve

Description:

By using syn_preserve attribute, the user can avoid any optimization of a register signal directly in the design code. The syntax is the following one:

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

syn_preserve

IP

 

Methods

 

Table: Attribute SynPreserve environment

...

Board check: No board purpose for this testcase.

 


Board

Scope

Description:

The user can use NxScope IP by implementing it in the design code in order to check signals on a NanoXplore Evaluation board.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

NxScope NxScopeV2

Methods

 

Table: Board Scope environment

...

For NG-ULTRA, NxScopeV2 IP Core is used instead of NxScope.

Description:

The user can program a NanoXplore Evaluation board (DevKit) with a simple bitstream using switches and LEDs.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

True

Attributes

 

IP

 

Methods

 

Table: Board SwitchBlink environment

...

-> Make sure all this check points are OK.


ThermalSensor

Description:

The user can interface with the internal thermal sensor in order to retrieve the junction temperature.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM

Embedded

No

Simulation

No

Attributes

 

IP

 

Methods

initRegister

Table: Board ThermalSensor environment

...

Board check: Temperature bus is displayed on LEDs.

 


Component

ClockSwitch

Description:

The user can gate and mux clocks using NanoXplore macro cells in the design code.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

Yes

Attributes

 

IP

NX_CKS NX_GCK

Methods

 

Table: Component ClockSwitch environment

...

Board check: No board purpose for this testcase.

 

Ddfr

Description:

The user can use double data rate input/output using NanoXplore macro cells in the design code.

...

Here after the table of compliances for this testcase.

Variant

NG-ULTRA

Embedded

No

Simulation

Yes

Attributes

 

IP

NX_IDDFR NX_ODDFR

Methods

 

Table: Component Ddfr environment

...

Board check: No board purpose for this testcase.

DspConfig

Description:

The user can make operations using NanoXplore DSP macro cells in the design code.

Hereafter the list of available configurations:

NAME

Description

ADD36

36 bits adder

SUB36

36 bits subtractor

SMUL18

18 bits signed multiplicator

UMUL18

18 bits unsigned multiplicator

ADD36_PIPE

36 bits adder with input/output pipe stages

SUB36_PIPE

36 bits subtractor with input/output pipe stages

SMUL18_PIPE

18 bits signed multiplicator with input/output pipe stages

UMUL18_PIPE

18 bits unsigned multiplicator with input/output pipe stages

Table: Component DspConfig configuration description

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE

Embedded

Yes

Simulation

Yes

Attributes

 

IP

NX_DSP_WRAP

Methods

 

Table: Component DspConfig environment

...

Board check: No board purpose for this testcase.

 


IoConfig

Description:

The user can make operations using NanoXplore IO macro cells in the design code.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

NX_IOB

Methods

 

Table: Component IoConfig environment

...

Board check: No board purpose for this testcase.

 

 


PllConfig

Description:

The user can generate clocks using NanoXplore PLL macro cells in the design code.

Hereafter the list of available configurations:

NAME

Description

DELAY

Feedback clock is delayed

REF_DIVIDED (MEDIUM) /

OSC_REF (LARGE/ULTRA)

Input REF is divided as reference clock /

Internal oscillator is used and divided as reference clock

OUT_DIVIDED

All outputs get a not null divider

EXT_FBK

Feedback is external

Table: Component PllConfig configuration description

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

Yes

Attributes

 

IP

NX_PLL

Methods

 

Table: Component PllConfig environment

...

Board check: No board purpose for this testcase.

 


RamConfig

Description:

The user can store data using NanoXplore RAM macro cells in the design code.

Hereafter the list of available configurations:

NAME

Description

NOECC

2kx24 memory with rising edge clock without ECC

FAST

2kx18 memory with rising edge clock with ECC detection only

SLOW

2kx18 memory with rising edge clock with ECC read repairing

NOECC_PIPE

2kx24 memory with falling edge clock without ECC with input/output pipe stages

FAST_PIPE

2kx18 memory with falling edge clock with ECC detection only with input/output pipe stages

SLOW_PIPE

2kx18 memory with falling edge clock with ECC read repairing with input/output pipe stages

Table: Component RamConfig configuration description

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

Yes

Attributes

 

IP

NX_RAM_WRAP

Methods

 

Table: Component RamConfig environment

...

Board check: No board purpose for this testcase.

 


RfbConfig

Description:

The user can store data using NanoXplore Register File macro cells in the design code.

Hereafter the list of available configurations for MEDIUM/LARGE:

NAME

Description

FALLING

Write and Read accesses are falling edge sensitive

RISING

Write and Read accesses are rising edge sensitive

Table: Component RfbConfig configuration description MEDIUM/LARGE

Hereafter the list of available configurations for ULTRA:

NAME

Description

SPRAM

Single port RFB

FALLING DPRAM

Dual port RFB falling edge sensitive

RISING DPRAM

Dual port RFB rising edge sensitive

WIDTH_EXT

2 RFB are used for twice larger words

HIGHT_EXT

2 RFB are used for twice larger number of words

2R1W

2 RFB are used for 2 read ports

RISING_FIFO_WIDTH_EXT

FIFO: 2 RFB are used for twice larger words

RISING_FIFO_HEIGHT_EXT

FIFO: 2 RFB are used for twice larger number of words

Table: Component RfbConfig configuration description ULTRA

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

Yes

Attributes

 

IP

NX_RFB_WRAP NX_RFBDP_U_WRAP NX_RFBSP_U_WRAP NX_XRFB_32x36 NX_XRFB_64x18 NX_XFIFO_64x18 NX_XFIFO_32x36

Methods

 

Table: Component RamConfig environment

...

Board check: No board purpose for this testcase.


Service

Description:

The user can interface with the Bitstream Manager and the Service bank using NanoXplore Service macro cell in the design code.

...

Here after the table of compliances for this testcase.

Variant

NG-ULTRA

Embedded

No

Simulation

Yes

Attributes

 

IP

NX_SERVICE_WRAP

Methods

createClock

Table: Component Service environment

...

Board check: No board purpose for this testcase.

 


Soc

Description:

The user can interface with the Soc using NanoXplore SOC_INTERFACE macro cell in the design code.

...

Here after the table of compliances for this testcase.

Variant

NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

NX_SOC_INTERFACE_WRAP

Methods

 

Table: Component Soc environment

...

Board check: No board purpose for this testcase.

 

 


WfgConfig

Description:

The user can generate clocks using NanoXplore WFG macro cells in the design code.

Hereafter the list of available configurations:

NAME

Description

BYPASS

Input is directly routed to the output

BYPASS_INVERT

Input is inverted to generate output

DIV2

Input is divided by 2 with a pattern to generate output with rising edge generation

DIV2_FALLING

Input is divided by 2 with a pattern to generate output with falling edge generation

DIV2_DELAY

Input is divided by 2 with a pattern to generate output with an additional delay

DIV16

Input is divided by 16 with a pattern to generate output

DIV40 (ULTRA)

Input is divided by 16 with a divider to generate output

Table: Component WfgConfig configuration description

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

Yes

Attributes

 

IP

NX_WFG

Methods

 

Table: Component WfgConfig environment

...

Board check: No board purpose for this testcase.


Design

DelayIo

Description:

The user can drive delays on IO statically or dynamically using NanoXplore macro cells in the design code.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE

Embedded

No

Simulation

No

Attributes

 

IP

NX_WFG NX_IOM_CONTROL NX_IOM_DRIVER NX_IOB

Methods

createClock

Table: Design DelayIo environment

...

Board check: No board purpose for this testcase.

 


 

DspCascaded

Description:

The user can cascade DSP using NanoXplore DSP macro cells in the design code in order to compute large operations.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

NX_DSP_SPLIT

Methods

Table: Design DspCascaded environment

...

Board check: No board purpose for this testcase.

 


DspMultAcc

Description:

The user can infer a 12*16+36 operations mapped in DSP.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

 

Table: Design DspMultAcc environment

...

Board check: No board purpose for this testcase.

 


DspTranspose

Description:

The user can implement a 6-tap transpose Finite Impulsion Response filter.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

NX_TRANSPOSE_FIR

Methods

 

Table: Design DspTranspose environment

...

Board check: No board purpose for this testcase.

 


LowskewManagement

Description:

The user can interface with the low-skew network through several ways.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

NX_BD NX_GCK NX_WFG

Methods

Table: Design LowskewManagement environment

...

Board check: No board purpose for this testcase.

 


MemInfer

Description:

The user can infer memories without instantiating NanoXplore macro cells in the design code.

Hereafter the list of all inferred memories:

NAME

Description

ROM

Read Only Memory

SPRAM

Single-Ported Random-Access Memory

DPRAM

Double-Ported Random-Access Memory

SPRAM_ECC

Single-Ported Random-Access Memory with Error Code Correction

DPRAM_ECC

Double-Ported Random-Access Memory with Error Code Correction

Table: Design MemInfer configuration description

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

NX_ECC

Methods

 

Table: Design MemInfer environment

...

Board check: No board purpose for this testcase.

 


Init

Ram

Description:

The user can initialize a memory using the addMemoryInitialization NXpython method in the python script. The syntax is the following one:

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

Yes

Attributes

 

IP

 

Methods

addMemoryInitialization getInstances

Table: Init Ram environment

...

Board check: No board purpose for this testcase.


Ip

CrossDomain

Description:

The user can cross clock domain properly thanks to NanoXplore IP. Implemented IP are:

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

Yes

Attributes

 

IP

IP_CDC FIFO

Methods

addIp

Table: Ip CrossDomain environment

...

Board check: No board purpose for this testcase.


 

Ddr2Dfi

Description:

The user can interface with a DDR2 memory thanks to the NanoXplore DDR2 DFI IP.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE

Embedded

No

Simulation

No

Attributes

 

IP

IP_DFI

Methods

addIp

Table: Ip Ddr2Dfi environment

...

Board check: Switches and leds allow to control and receive data.


HsslEsistream

Description:

The user can interface with HSSL links thanks to the NanoXplore HSSL macro cell.

...

Here after the table of compliances for this testcase.

Variant

NG-LARGE

Embedded

No

Simulation

No

Attributes

 

IP

NX_HSSL_L_FULL

Methods

addHSSLLocation constrainModule

Table: Ip HsslEsistream environment

...

  • ERROR FLAG deactivated on J15 PIN1

  • HSSL_CLK at 48MHz on J15 PIN3

  • ESISTREAM SYNC RX/TX activated on J15 PIN 5

  • RX_PLL_LOCKED activated on J15 PIN7

  • PMA RX CLOCK on on J15 PIN13


R5AxiMaster

Description:

The user can interface with R5 Core thanks to the NanoXplore R5 interface macro cell.

...

Here after the table of compliances for this testcase.

Variant

NG-LARGE

Embedded

No

Simulation

No

Attributes

 

IP

NX_R5_L_WRAP NX_SCOPE NX_PLL NX_WFG

Methods

addMemoryInitialization addMappingDirective

Table: Ip R5AxiMaster environment

...

Board check: No board purpose for this testcase.


R5AxiSlave

Description:

The user can interface with R5 Core thanks to the NanoXplore R5 interface macro cell.

...

Here after the table of compliances for this testcase.

Variant

NG-LARGE

Embedded

No

Simulation

No

Attributes

 

IP

NX_R5_L_WRAP NX_SCOPE NX_PLL NX_WFG

Methods

addMemoryInitialization addMappingDirective

Table: Ip R5AxiSlave environment

...

Board check: No board purpose for this testcase.


R5Jtag

Description:

The user can interface with R5 Core thanks to the NanoXplore R5 interface macro cell.

...

Here after the table of compliances for this testcase.

Variant

NG-LARGE

Embedded

No

Simulation

No

Attributes

 

IP

NX_R5_L_WRAP

Methods

 

Table: Ip R5Jtag environment

...

Board check: No board purpose for this testcase.


Serdes

Description:

The user can send and receive data at high speed thanks to the NanoXplore SERDES macro cells.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE

Embedded

No

Simulation

No

Attributes

 

IP

NX_SER NX_DES NX_WFG

Methods

 

Table: Ip Serdes environment

...

Board check: No board purpose for this testcase.


SpacewireLoopback

Description:

The user can communicate with Spacewire link thanks to the NanoXplore SpaceWire macro cell.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE

Embedded

No

Simulation

No

Attributes

 

IP

IP_SPW_BANK IP_FIFO_part NX_PLL NX_WFG

Methods

addIp

Table: Ip SpacewireLoopback environment

...

3- Check data is displayed on LED.


SpacewireRoadmap

Description:

The user can communicate with Spacewire link and Roadmap protocol thanks to the NanoXplore SpaceWire macro cell.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE

Embedded

No

Simulation

No

Attributes

 

IP

NX_PLL NX_WFG

Methods

 

Table: Ip SpacewireRoadmap environment

...

Board check: No board purpose for this testcase.

SpacewireRx

Description:

The user can retrieve data from a Spacewire Link generating the recovery clock.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

spw_rx

Methods

 

Table: Ip SpacewireRx environment

...

Board check: Data are routed to output LED (falling edge data on LED1 + rising edge data on LED2).


MappingDirective

BlackBox

Description:

The user can declare a component which is a blackbox and map it into the desired NanoXplore macro cell using addBlackbox NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

addBlackBox

Table: MappingDirective Blackbox environment

...

Board check: No board purpose for this testcase.


Memory

Description:

The user can map inferred operations into the desired NanoXplore macro cell using addMappingDirective NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

addMappingDirective getModels

Table: MappingDirective Memory environment

...

Board check: No board purpose for this testcase.

 

Operator

Description:

The user can map inferred operations into the desired NanoXplore macro cell using addMappingDirective NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

addMappingDirective getModels getInstances

Table: MappingDirective Operator environment

...

Board check: No board purpose for this testcase.


Pad

Parameter

Description:

The user can configure pads with many parameters using addPad or modifyPad NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

 

Methods

addPad

Table: Pad Parameter environment

...

Board check: No board purpose for this testcase.


Registered

Description:

The user can map registers, mapped by default in NX_DFF and located in tiles, into NX_DFR located in the pad using addPad NXpython method and registered parameter.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

 

Methods

addPad

Table: Pad Registered environment

...

Board check: No board purpose for this testcase.

 


PlacingConstraint

Aperture

Description:

The user can focus its design into a defined area using modifyAperture NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

modifyAperture

Table: PlacingConstraint Aperture environment

...

Board check: No board purpose for this testcase.


ConstrainPath

Description:

The user can confine the path between registers in a region using constrainpath NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

constrainPath

Table: PlacingConstraint ConstrainPath environment

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

exportSites

Table: PlacingConstraint ExportSites environment

...

Board check: No board purpose for this testcase.

Focus

Description:

The user can focus its design around a point using setFocus NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

setFocus

Table: PlacingConstraint Focus environment

...

Board check: No board purpose for this testcase.

Obstruction

Description:

The user can remove regions from available area in the tool using addObstruction and modifyObstruction NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

addObstruction modifyObstruction

Table: PlacingConstraint Obstruction environment

...

Board check: No board purpose for this testcase.

PreplaceIp

Description:

The user can preplace an IP and declare IP as a blackbox using addBlackBox NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

addBlackBox modifyAperture

Table: PlacingConstraint PreplaceIp environment

...

Board check: No board purpose for this testcase.

Region

Description:

The user can confine a module in a region using addModule, createRegion addRegion and confineModule or directly constrainModule NXpython methods.

...

Code Block
p.addModule('up_counter','GEN_HIER2.COUNTER0','GEN_HIER2_COUNTER0-%','Soft')

p.createRegionaddRegion('HIER2_COUNTER0', 13, 6, 142, 83,False)

p.confineModule('GEN_HIER2_COUNTER0-0', 'HIER2_COUNTER0')

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

createRegion

addRegion removeRegion modifyRegion addModule confineModule constrainModule removeSoftModules

Table: PlacingConstraint Region environment

...

Board check: No board purpose for this testcase.


RingLocation

Description:

The user can place manually PLL and WFG into a CKG using respectively addPLLLocation and addWFGLocation NXpython methods. The method addRingLocation can be used too in both cases.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

addWFGLocation addPLLLocation addRingLocation

Table: PlacingConstraint RingLocation environment

...

Board check: No board purpose for this testcase.


Site

Description:

The user can place manually a fabric element (LUT, DFF, RF, CY, RAM,DSP) into a TILE/CGB using setSite NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

setSite clearFabricPrePlaceConstraints

Table: PlacingConstraint Site environment

...

Board check: No board purpose for this testcase.

ProcessingSystem

Interruptions

Description:

The user can generate interruptions from the Fabric to the SoC through SoC interface.

...

Here after the table of compliances for this testcase.

Variant

NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

 NX_SOC_INTERFACE

Methods

Table: ProcessingSystem Interruptions environment

...

Board check: Check interruptions are received by the SoC when using switches.

Watchdog

Description:

The user can use watchdogs from processing system cores.

...

Here after the table of compliances for this testcase.

Variant

NG-ULTRA

Embedded

No

Simulation

No

Attributes

 

IP

 NX_SOC_INTERFACE

Methods

Table: ProcessingSystem Interruptions environment

...

Board check: Check LED associated to the programmed watchdog is switched when watchdog counter limit is reached.

StaConstraint

CaseAnalysis

Description:

The user can specify a case analysis for the STA using setCaseAnalysis NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

setCaseAnalysis createClock setClockGroup getClockNet getNet

Table: StaConstraint ClockGroup environment

...

Board check: No board purpose for this testcase.

ClockGroup

Description:

The user can specify unrelated clocks using setClockGroup NXpython method or calling SDC constraint.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

createClock setClockGroup getClock

Table: StaConstraint ClockGroup environment

...

Board check: No board purpose for this testcase.


DelayPath

Description:

The user can specify path delays between registers by using addMinDelayPath, addMaxDelayPath and addMulticyclePath NXpython methods or calling SDC constraints.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

addMaxDelayPath addMinDelayPath addMulticyclePath getRegister

Table: StaConstraint DelayPath environment

...

Board check: No board purpose for this testcase.


FalsePath

Description:

The user can specify path to be ignored by the STA by using addFalsePath, NXpython method or calling SDC constraint.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

addFalsePath getRegister getRegisters getRegistersByClock getPort createClock

Table: StaConstraint FalsePath environment

...

Board check: No board purpose for this testcase.


GeneratedClock

Description:

The user can create a clock directly or specifying its relationship with another clock using respectively createClock and createGenerateClock NXpython method.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

createClock createGeneratedClock getPort getClockNet getRegisterClock

Table: StaConstraint GeneratedClock environment

...

Board check: No board purpose for this testcase.


InputOutputDelay

Description:

The user can apply a minimum and a maximum data arrival time on inputs and outputs using respectively setInputDelay and setOutputDelay NXpython methods.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

createClock getPort getPorts getClock setInputDelay setOutputDelay

Table: StaConstraint InputOutputDelay environment

...

Board check: No board purpose for this testcase.

ReportPath

Description:

The user can generate timing reports between two pins or two registers with respectively reportPath or addReportPath and reportTiming or addReportTimingPath NXpython methods.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

createClock reportPath addReportPathRequest reportTiming addReportTimingRequest removeReportPathRequest removeReportTimingRequest clearTimingConstraints getRegister getPin getPort getProject getAnalyzer

Table: StaConstraint ReportPath environment

...

Board check: No board purpose for this testcase.

SpacewireTiming

Description:

The user must be able to get all needed timing in case of recovery clock like Spacewire one.

...

Here after the table of compliances for this testcase.

Variant

NG-MEDIUM NG-LARGE NG-ULTRA

Embedded

Yes

Simulation

No

Attributes

 

IP

 

Methods

createClock

Table: StaConstraint SpacewireTiming environment

...