sds++/sdscc Compiler Commands
This section describes the SDSoC™
sds++
compiler commands and options.
sds++/sdscc
compilers are based on GCC, and therefore support many
standard GCC options which are not documented here. For information refer to the GCC Option Index. Compiler Commands
sdscc – SDSoC C compiler
sds++ - SDSoC C++ compiler
Command Synopsis
sdscc/sds++
[hardware_function_options] [system_options]
[merge_options] [performance_estimation_options]
[options_passed_through_to_cross_compiler]
[-sds-pf platform_name] [-sds-pf-info platform_name]
[-sds-pf-list] [-sds-sys-config configuration_name]
[-sds-proc processor_name] [-target-os os_name]
[-sds-pf-path path] [-sds-image image_name]
[-sds-clang-filter option_file]
[-debug-xrf] [-debug-xrf-cc compiler_name]
[-verbose] [-version] [--help] [files]
Hardware Function Options
[-sds-hw function_name source_file
[-clkid clock_id_number]
[-files hls_file_list]
[-hls-target boolean_value]
[-hls-target-flags "target_options"]
[-hls-tcl hls_tcl_directives_file]
[-shared-aximm]
-sds-end]*
For detail on these commands, see Hardware Function Options.
Performance Estimation Options
[[-perf-funcs function_name_list -perf-root function_name]
| [-perf-est data_file] [-perf-est-hw-only]]
For detail on these commands, see SDSCC/SDS++ Performance Estimation Flow Options.
Merge Options
[-merge input_project_directory [input_project_directory]*
[-o output_project_directory]
[-emulation <mode>]
[-disable-ip-cache]
[-maxjobs number]
[-maxthreads number]
[-mno-bitstream]
[-mno-boot-files]
[-remote-ip-cache cache_directory]
[-xp xpvalue]]
For detail on these commands, see SDSCC/SDS++ Performance Estimation Flow Options.
System Options
[[-ac function_name:clock_id_number]* [-apm]
[-bsp-config-file mss_file] [-bsp-config-merge-file mss_file]
[-debug-port function:argument]
[-disable-ip-cache] [-dk chipscope:instance:port]
[-dm-sharing sharing_level]
[-dmclkid clock_id_number] [-emulation <mode>]
[-impl-strategy implementation strategy] [-instrument-stub]
[-maxjobs number] [-maxthreads <1-8>] [-mno-bitstream]
[-mno-boot-files] [-rebuild-hardware]
[-remote-ip-cache cache_directory]
[-sdcard data_directory]
[-synth-strategy synthesis_strategy]
[-trace] [-trace-no-sw] [-trace-buffer]
[-vpl-ini ini_file] [-xp xpvalue]]
For details on these commands, see System Options.
The sds++
compiler compiles and links
C/C++ source files into an application-specific hardware/software system-on-a-chip (SoC)
implemented on a Zynq®-7000 SoC or Zynq® UltraScale+™ MPSoC device.
The command usage and options are identical for sdscc
and sds++
. Options not recognized by
sds++
are passed to the Arm® cross-compiler. Compiler options within an -sds-hw ... -sds-end
clause are ignored for the -c
foo.c
option when foo.c
is not the file
containing the specified hardware function.
When linking the application ELF, sds++
creates and implements the hardware system. It also generates an SD card image containing
the ELF and boot files required to initialize the hardware system, configures the
programmable logic, and runs the target operating system.
When linking application ELF files for non-Linux targets, for example
Standalone or FreeRTOS, default linker scripts found in the folder <install_path>/platforms/<platform_name> are used. If a
user-defined linker script is required, it can be specified using the –Wl,-T –Wl,<path_to_linker_script>
linker option.
When building a system that has no hardware accelerated functions,sds++
can reduce build time by using
pre-built
hardware provided by the target platform.
Report and log files are found in the _sds/reports folder.
When running Linux applications that use shared libraries, the libraries must be contained in the root file system or SD card and the path to the libraries added to the LD_LIBRARY_PATH environment variable.
System Options
The sds++
compiler compiles and links
C/C++ source files into an application-specific hardware/software system-on-a-chip (SoC)
implemented on a Zynq®-7000 SoC or Zynq® UltraScale+™ MPSoC device.
Options not recognized by sds++
are
passed to the Arm® cross-compiler. Compiler options
within an -sds-hw ... -sds-end
clause are ignored for the
-c foo.c
option when foo.c
is not the file containing the specified hardware function.
When linking the application ELF, sds++
creates and implements the hardware system. It also generates an SD card image containing
the ELF and boot files required to initialize the hardware system, configures the
programmable logic, and runs the target operating system.
When linking application ELF files for non-Linux targets, for example
Standalone or FreeRTOS, default linker scripts found in the folder <install_path>/platforms/<platform_name> are used.
If a user-defined linker script is required, it can be specified using the –Wl,-T –Wl,<path_to_linker_script>
linker option.
When building a system containing no functions marked for hardware
implementation, sds++
uses pre-built hardware when
available for the target platform.
Report and log files are found in the _sds/reports folder.
When running Linux applications that use shared libraries, the libraries must be contained in the root file system or SD card and the path to the libraries added to the LD_LIBRARY_PATH environment variable.
Optional PL Configuration After Linux Boot
Whensds++
creates a bitstream .bin file in the sd_card
folder, it can be used to configure the PL after booting Linux and before running the
application ELF. The embedded Linux command used is cat bin_file >
/dev/xdevcfg
.General Options
The following command line options are applicable for any
sds++
invocation or your display information.
Option | Valid Values | Description |
---|---|---|
-sds-pf
<platform_name> |
<platform_name> |
Specifies the target platform that defines the base system
hardware and software, including operation system and boot files. The <platform_name> can be the name of a platform in the
SDSoC environment installation or a file path
to a folder containing platform files with the last component of the path matching the
platform name.The platform defines the base hardware and software,
including operation system and boot files. Use this option when compiling
accelerator source files and when linking the ELF file. Use the |
-sds-pf-info
<platform_name> |
<platform_name> |
Displays general information about a platform. Use the –sds-pf-list option to list available platforms. The
information displayed includes available system configurations that can be specified
with the -sds-sys-config system_configuration
option.
|
-sds-pf-list |
N/A | Displays a list of available platforms and exit (if no other
options are specified). The information displayed includes available system
configurations that can be specified with the -sds-sys-config system_configuration option. |
-sds-sys-config
<configuration_name> |
<configuration_name> |
Specifies the system configuration that defines the software
platform used, which includes the target operating system and other settings. The
-sds-pf-list and -sds-pf-info options can be used to list the available system
configurations for a platform.When the
|
-sds-proc
<processor_name> |
<processor_name> |
Specifies the processor name to use with the system
configuration defined by the -sds-sys-config option.
A system configuration normally specifies a target CPU and this option is not
required.
|
-sds-pf-path
<path> |
<path> |
Specifies a search path for platforms. The specified path can
contain one or more sub-folders, each of which is a platform folder.
|
-sds-image
<image_name> |
<image_name> |
Used with the -sds-sys-config
option, this specifies the SD card image to use. If this option is not specified, the
default image is used.
|
-target-os
<os_name> |
<linux | standalone | freertos > |
Specifies the target operating system. The selected OS
determines the compiler toolchain used and includes file and library paths added by
sds++ . For a list of valid os_name options, use the command sdscc
-sds-pf-info <plat_name> .If the If you do not specify the |
-debug-xrf |
N/A | Creates Vivado® HLS debug cross reference information when compiling functions for hardware, adding the config_debug Tcl command. |
-debug-xrf-cc
<compiler> |
<compiler> |
Specifies the compiler executable used to compile accelerator
source files for debug cross reference symbols (defaults to xcpp if not specified). If the path to the executable is not defined, use
the PATH from the environment. If used, specify -debug-xrf-cc for both compile and link command lines. |
-verbose |
N/A | Prints verbose output to STDOUT. |
-version |
N/A | Prints the sds++ version
information to STDOUT. |
--help |
N/A | Prints command line help information. Note that two consecutive
hyphen or dash characters - are used. |
The following command line options are applicable only to sds++
invocations used to compile a source file.
Hardware Function Options
Hardware function options provide a means to consolidate
sdscc
/sds++
options within a
Makefile to simplify command line calls and make minimal
modifications to a pre-existing Makefile.
-sds-hw
and -sds-end
options are used in pairs: - The
-sds-hw
option begins the description of a single function being moved into hardware. -sds-end
option terminates the list of configuration details for that function.
-sds-hw
as the start of the configuration and -sds-end
as the terminator.–sds-hw
blocks to collect all options in the SDSFLAGS
Makefile variable and to replace an original definition of
CC
with sds++ ${SDSFLAGS}
.
Thus the original Makefile for an application can be
converted to an sds++
compiler Makefile with minimal
changes.APPSOURCES = add.cpp main.cpp
EXECUTABLE = add.elf
CROSS_COMPILE = arm-xilinx-linux-gnueabi-
AR = ${CROSS_COMPILE}ar
LD = ${CROSS_COMPILE}ld
#CC = ${CROSS_COMPILE}g++
PLATFORM = zc702
SDSFLAGS = -sds-pf ${PLATFORM} \
-sds-hw add add.cpp -clkid 1 -sds-end \
-dmclkid 2
CC = sds++ ${SDSFLAGS}
INCDIRS = -I..
LDDIRS =
LDLIBS =
CFLAGS = -Wall -g -c ${INCDIRS}
LDFLAGS = -g ${LDDIRS} ${LDLIBS}
SOURCES := $(patsubst %,../%,$(APPSOURCES))
OBJECTS := $(APPSOURCES:.cpp=.o)
.PHONY: all
all: ${EXECUTABLE}
${EXECUTABLE}: ${OBJECTS}
${CC} ${OBJECTS} -o $@ ${LDFLAGS}
%.o: ../%.cpp
${CC} ${CFLAGS} $<
Option | Valid Values | Description |
---|---|---|
-sds-hw function_name
source_file |
N/A | An sds++ command line can include zero
or more –sds-hw blocks. Each block is associated with a
top-level hardware function specified as the first argument and its containing source file
specified as the second argument. If the file name associated with an -sds-hw block matches the source file to be compiled, the options are applied.
Options outside of –sds-hw blocks are applied where
applicable.When using the xfOpenCV library, the |
-clkid <n> |
<n> has one of the values
listed in the Clock ID Values by Platform table. |
Sets the accelerator clock ID to |
-files file_list |
file_list is a list of one or more
files required to compile the current top-level function into hardware using Vivado HLS. |
Specifies a comma-separated list (without white space) of one or more
files required to compile the current top-level function into hardware using Vivado HLS. If any of these files contain source code that is
not used by HLS but is required to produce the application executable, they must be compiled
separately to create object files (.o), and linked with
other object files during the link phase. When using the xfOpenCV library,
the |
-hls-target boolean_value |
boolean_value is 0|1 |
When set to 1, in Vivado HLS
add_files commands, insert -target and Arm GNU toolchain include options
in addition to -m32 or -m64 options. When set to 0, insert Use this option if the default behavior results in target dependent compilation errors. When specified outside of |
-hls-target-flags "target_options" |
"target_options" are options in the Vivado HLS
add_files command. |
Specifies a list of target options to use in place of automatically
inserted options in the Vivado HLS add_files command, for example -m32 or -m64 . The options must be enclosed in
quotes so they will not be interpreted as compiler options. |
-hls-tcl
hls_tcl_directives_file |
N/A | When using the Vivado HLS tool to
synthesize the hardware accelerator, source the specified Tcl file containing HLS directives.
During HLS synthesis, sds++ creates a run.tcl file used to drive the Vivado HLS tool. In this Tcl file, the following commands are
inserted:
If the |
-shared-aximm |
N/A | Shares AXIMM ports instead of enabling multiple ports. |
-sds-end |
N/A | Specifies the end of the -sds-hw
options for the specified function_name . |
Clock ID Values by Platform
For a list of clock ID values by platform, see Clock ID Values by Platform.
SDSCC/SDS++ Performance Estimation Flow Options
A full bitstream compile can take much more time than a software compile, so
the sds++/sdscc
(referred to as sds++
) applications provide performance estimation options to compute the
estimated runtime improvement for a set of hardware function calls.
In the Application Project Settings pane, to invoke the estimator, select the Estimate Performance check box. This enables performance estimation for the current build configuration and builds the project.
Estimating the speed-up is a two phase process:
- The SDSoC environment compiles the hardware functions
and generates the system. Instead of synthesizing the system to bitstream, the
sds++
computes an estimate of the performance based on estimated latencies for the hardware functions and data transfer time estimates for the callers of hardware functions. - In the generated Performance Report, to determine a performance baseline and the performance estimate, select Click Here to run an instrumented version of the software on the target.
See the SDSoC Environment Getting Started Tutorial (UG1028) for a tutorial on how to use the Performance Report.
You can also generate a performance estimate from the command line. As a
first pass to gather data about software runtime, use the -perf-funcs
option
to specify functions to profile and -perf-root
to specify the root function
encompassing calls to the profiled functions.
The sds++
system compiler then automatically
instruments these functions to collect runtime data when the application is run on a board.
When you run an instrumented application on the target, the program creates a file on the SD
card called swdata.xml, which contains the runtime
performance data for the run.
Copy the swdata.xml to
the host, and run a build that estimates the performance gain on a per hardware function
caller basis and for the top-level function specified by the –perf-root
function in the first pass run. Use the –perf-est
option to specify swdata.xml as
input data for this build.
The following table specifies the sds++
system compiler
options normally used to build an application.
Option | Description |
---|---|
-perf-funcs function_name_list |
Specifies a comma separated list of all functions to be profiled in the instrumented software application. |
-perf-root function_name |
Specifies the root function encompassing all calls to the profiled functions. The default is the function main. |
-perf-est data_file |
Specifies the file containing runtime data generated by the instrumented software application when run on the target. Estimate performance gains for hardware accelerated functions. The default name for this file is swdata.xml. |
-perf-est-hw-only |
Runs the estimation flow without running the first pass to collect software run data. Using this option provides hardware latency and resource estimates without providing a comparison against baseline. |
cd /; sync; umount /mnt;
. This ensures that the swdata.xml file is written out to the SD card.Compiler Macros
Predefined macros allow you to guard code with
#ifdef
and #ifndef
preprocessor statements. The macro names begin and end with two underscore
characters ‘_’. The __SDSCC__
macro is defined
whenever sdscc
or sds++
(referred to collectively as sds++
) is used to compile source files. It can be used to guard code
depending on whether it is compiled by sds++
or
another compiler, for example GCC
.
When sds++
compiles source files
targeted for hardware acceleration using Vivado HLS, the __SDSVHLS__
macro is defined to be used to guard code
depending on whether high-level synthesis is run or not.
__SDSCC__
macro to use the sds_alloc()
and sds_free()
functions when compiling source code with sds++
, malloc()
, and
free()
when using other
compilers.#ifdef __SDSCC__
#include <stdlib.h>
#include "sds_lib.h"
#define malloc(x) (sds_alloc(x))
#define free(x) (sds_free(x))
#endif
__SDSVHLS__
macro is used to guard code in a function definition that
differs depending on whether it is used by Vivado HLS to generate hardware or used in a software
implementation.#ifdef __SDSVHLS__
void mmult(ap_axiu<32,1,1,1> A[A_NROWS*A_NCOLS],
ap_axiu<32,1,1,1> B[A_NCOLS*B_NCOLS],
ap_axiu<32,1,1,1> C[A_NROWS*B_NCOLS])
#else
void mmult(float A[A_NROWS*A_NCOLS],
float B[A_NCOLS*B_NCOLS],
float C[A_NROWS*B_NCOLS])
#endif
In addition, the macro, HLS_NO_XIL_FPO_LIB
, is defined prior to the include option for
Vivado HLS headers and is visible to
Vivado HLS, SDSoC
analysis tools, and target cross-compilers. This macro disables the use of
bit-accurate, floating-point simulation models, instead using the faster (although
not bit-accurate) implementation from your local system. Bit-accurate simulation
models are not provided for Zynq-7000 SoC and Zynq UltraScale+ MPSoC
Arm targets.
System Options
Option | Description |
---|---|
-ac
<function_name>:<clock_id_number> |
Uses the specified clock ID number for an RTL accelerator function in a C-Callable IP library instead of the default clock ID. |
-apm |
Inserts an AXIAXI Performance Monitor IP block to monitor all generated hardware/software interfaces. Within the SDSoC development environment, in the Debug perspective, you can activate the APM prior to running your application by clicking the Start button within the Performance Counters View. See the SDSoC Environment Getting Started Tutorial (UG1028) for more information. |
-bsp-config-file
<mss_file> |
Specifies the path to a board support package (BSP)
configuration file (.mss) to use
instead of an automatically-generated file for a bare-metal based target
OS, for example Standalone or FreeRTOS. When using this option, also add
an include option specifying the path to your BSP header files: -I</path/to/includes> |
-bsp-config-merge-file
<mss_file> |
Specifies the path to a board support package (BSP)
configuration file (.mss) to use
for the base platform and merge using hardware information from the
final design to create a BSP configuration file contain user settings
for the base platform plus settings for hardware added to the base
platform; for example, DMA drivers. This merged BSP configuration file
is used instead of an automatically generated file for a bare-metal
based target OS, for example, Standalone or FreeRTOS. When using this
option, add an include option specifying the path to your BSP header
files: -I</path/to/includes> . |
-debug-port
function:argument |
Specifies a function and argument to monitor using a
System ILA module. Multiple |
-disable-ip-cache |
Do not use a cache of pre-synthesized IP cores. The
use of IP caching reduces the overall build time by eliminating the
synthesis step for static IP cores. If the resources required to
implement the hardware system exceeds available resources by a small
amount, the -disable-ip-cache option
forces sds++ to synthesize all IP
cores in the context of the design and might reduce resource usage
enough to enable implementation. |
-dmclkid
<n> |
Sets the data motion network clock ID to <n> , where <n> has one of the values listed in Clock ID Values by Platform. You can use the
command sds++ –sds-pf-info
platform_name to display the information about the
platform. If the dmclkid option is not
specified, the default value for the platform is used. Use the command
sds++ –sds-pf-list to list
available platforms and settings. |
-dk
chipscope:instance:port |
Specifies an instance name and port to monitor using
a System ILA module. Multiple -dk
options can be specified, instantiating a System ILA as needed. For
special cases, use the option --xp
param:compiler.userPostSysLinkTcl=<file> to specify a
Tcl file containing VivadoIP integrator Tcl commands to
post-process the System ILA in the block diagram after system linking
and before synthesis.Note:
--dk is also
accepted. |
-dk
list_ports |
Lists available instance and port names for System
ILA insertion. This option can only be specified when linking the design
and you can specify -mno-bitstream to
exit, review <pwd>/_sds/p0/dk_list_ports.txt , and update the
command line to create the bitstream.Note:
--dk is also
accepted. |
-dm-sharing
<n> |
The –dm-sharing
<n> option enables exploration of data mover sharing
capabilities if the initial schedule can be relaxed. The level of
sharing defaults to 0 (low) if not specified. Other values are 1
(medium), 2 (high), and 3 (maximum – schedule can be relaxed
infinitely). For example, to enable maximum data mover sharing, add the
sds++
-dm-sharing 3 option. |
-emulation <mode>
|
Generates files required to run emulation of the
system using QEMU for the processing subsystem and the Vivado Logic Simulator for the
programmable logic. This only works on boards that enable this flow
(currently Xilinx
base
platforms only). The <mode>
specifies the type of simulation models created for the PL, debug , or optimized . In the same directory that you ran sds++ , type the sdsoc_emulator command to run the emulation in the current
shell. |
-impl-strategy
<strategy_name> |
Specifies the Vivado implementation strategy name to use instead of the
default strategy, for example Performance_Explore. The strategy name can
be found in the Vivado
Implementation Settings dialog box in the Strategy menu, and the
strategies are described in this link in the Vivado Design Suite User Guide:
Implementation (UG904). Note: When creating the Tcl file for
synthesis and implementation, this command is added:
set_property strategy <strategy_name>
[get_runs impl_1] . |
-instrument-stub |
The –instrument-stub option instruments the generated hardware
function stubs with calls to the counter function sds_clock_counter() . When a hardware
function stub is instrumented, the time required to call send and
receive functions, as well as the time spent for waits, is displayed for
each call to the function. |
-maxjobs
<n> |
The -maxjobs
<n> option specifies the maximum number of jobs used
for Vivado synthesis. The default
is the number of cores divided by 2. |
-maxthreads
<n> |
The –maxthreads
<n> option specifies the number of threads used in
multithreading to speed up certain tasks, including Vivado placement and routing. The number
of threads can be an integer from 1 to 8. The default value is 4, but
the tools do not use more threads than the number of cores on the
machine. Also, a general limit based on the OS applies to all
tasks. |
-mno-bitstream |
Do not generate the bitstream for the design used to configure the programmable logic (PL). Normally a bitstream is generated by running the Vivado implementation feature, which can be time-consuming with run times ranging from minutes to hours depending on the size and complexity of the design. This option can be used to disable this step when iterating over flows that do not impact the hardware generation. The application ELF is compiled before bitstream generation. |
-mno-boot-files |
Do not generate the SD card image in the folder sd_card. This folder includes your application ELF and files required to boot the device and bring up the specified OS. This option disables the creation of the sd_card folder in case you would like to preserve an earlier version of this folder. |
-rebuild-hardware |
When building a software-only design with no
functions mapped to hardware, sds++
uses a pre-built bitstream if available within the platform, but use
this option to force a full system build. |
-remote-ip-cache
<cache_directory> |
Specifies the path to a directory used for IP
caching for Vivado synthesis. The
use of an IP cache can reduce the amount of time required for logic
synthesis for subsequent runs. The option --remote_ip_cache is also accepted. |
-sdcard
<data_directory> |
Specifies an optional directory containing additional files to include in the SD card image. |
-synth-strategy
<strategy_name> |
Specifies the Vivado synthesis strategy name to use instead of the
default strategy (for example, Flow_RuntimeOptimized). The strategy name
can be found in the Vivado
Synthesis Settings dialog box in the Strategy menu and the strategies
are described in this link in the Vivado
Design Suite User Guide: Synthesis (UG901). When creating
the Tcl file for synthesis and implementation, this command is added:
set_property strategy <strategy_name>
[get_runs synth_1] . |
-trace |
The –trace option
inserts hardware and software infrastructure into the design to enable
tracing functionality. |
-trace-buffer
<depth> |
The -trace-buffer
option specifies the trace buffer depth, which must be at least 16 and a
power of 2. If this option is not specified, the default value of 1024
is used. |
-trace-no-sw |
The –trace-no-sw
option inserts hardware trace monitors into the design without
instrumenting the software when enabling tracing functionality. |
-vpl-ini
<ini_file> |
Specifies an initialization file containing one
-xp <parameter_value> per
line, but do not include the -xp
option itself. This is equivalent to
specify
multiple -xp options on the command
line. Advanced users can use this option to customize the Vivado synthesis and implementation
flows. |
-xp
<xpvalue> |
Specifies a Vivado synthesis or implementation property or parameter,
optionally enclosed in double quotes. The <parameter_value> uses one of the following forms to
set a Vivado property or parameter,
respectively.
Familiarity with the Vivado tool suite is recommended to make the most use of these parameters. The first two examples set a Vivado property to specify a post-synthesis and post-optimization Tcl script, respectively:
The following example sets the maximum number of
threads used by Vivado and is
equivalent to using the
Advanced users can use the Normally, Vivado implementation does not produce a bitstream if
there are timing violations. To force
|
Clock ID Values by Platform
For a list of clock ID values by platform, see Clock ID Values by Platform.
Merge Options
The sds++ merge command supports a subset of sds++ linking options.
Option | Description |
---|---|
-merge
<input_dir> |
Specify one or more input SDSoC development environment project directories to be merged to create a single design (each contains _sds sub-directory). |
-o
<output_dir> |
Specify output directory to create the merged design (if omitted, use the current directory). |
<other_options> |
The following subset of the System Options are
supported:
|
Compiler Toolchain Support
The SDSoC environment uses the same GNU Arm cross-compiler toolchains included with the Xilinx Software Development Kit (SDK).
The Linaro-based GCC compiler toolchains support the Zynq-7000 SoC and Zynq UltraScale+ MPSoC family devices. This section includes additional information on toolchain usage.
When compiling and linking applications, use only object files and libraries
built using the same compiler toolchain and options as those used by the SDSoC environment. All SDSoC
provided software libraries and software components (Linux kernel, root filesystem, BSP
libraries, and other pre-built libraries) are built with the included toolchains. If you use
sdscc
/sds++
(referred to as
sds++
) to compile object files, the tools automatically insert
a small number of options. If you invoke the underlying toolchains, you must use the same
options.
For example, if you use a different Zynq-7000 SoC floating-point application binary interface (ABI), your binary objects are incompatible and cannot be linked with SDSoC Zynq-7000 binary objects and libraries.
The following table summarizes the sds++
usage
of Zynq-7000 SoC toolchains and options. Where options are
listed, you need to specify them only if you use the toolchain gcc
and g++
commands directly instead of invoking
sds++
.
Usage | Description |
---|---|
Zynq-7000 Arm bare-metal compiler and linker options | -mcpu=cortex-a9 -mfpu=vfpv3
-mfloat-abi=hard |
Zynq-7000 Arm bare-metal linker options | -Wl,--build-id=none
-specs=<specfile> Where the
|
Zynq-7000 Arm bare-metal compiler | ${SDX_install}/SDK/2019.1/gnu/aarch32/lin/gcc-arm-none-eabi/bin Toolchain prefix: gcc
executable: g++
executable: |
Zynq-7000 SDSoC bare-metal software (lib, include) | ${SDX_install}/SDK/2019.1/gnu/aarch32/lin/gcc-arm-none-eabi |
Zynq-7000 Arm Linux compiler | ${SDX_install}/SDK/2019.1/gnu/aarch32/lin/gcc-arm-linux-gnueabi/bin Toolchain prefix: gcc executable: g++ executable:
|
Zynq-7000 SDSoC Linux software (lib, include) | ${SDX_install}/SDK/2019.1/gnu/aarch32/lin/gcc-arm-linux-gnueabi |
The following table summarizes sds++
usage of
Zynq UltraScale+ MPSoC
Cortex™-A53 toolchains and options. Where options are
listed, you only need to specify them if you use the toolchain gcc
and g++
commands directly instead of invoking
sds++
.
Usage | Description |
---|---|
Zynq UltraScale+ MPSoC Arm bare-metal compiler and linker options | -mcpu=cortex-a53 -DARMR5 -mfloat-abi=hard
-mfpu=vfpv3-d16 |
Zynq UltraScale+ MPSoC Arm bare-metal linker options | -Wl,--build-id=none |
Zynq UltraScale+ MPSoC Arm bare-metal compiler | ${SDX_install}/SDK/2019.1/gnu/aarch64/lin/aarch64-none/bin Toolchain prefix: gcc executable: g++ executable: |
Zynq UltraScale+ MPSoC SDSoC bare-metal software (lib, include) | ${SDX_install}/SDK/2019.1/gnu/aarch64/lin/aarch64-none |
Zynq UltraScale+ MPSoC Arm Linux compiler | ${SDX_install}/SDK/2019.1/gnu/aarch64/lin/aarch64-linux/bin Toolchain prefix: gcc executable: g++ executable: |
Zynq UltraScale+ MPSoC SDSoC Linux software (lib, include) | ${SDX_install}/SDK/2019.1/gnu/aarch64/lin/aarch64-linux |
The following table summarizes the sds++
usage of Zynq UltraScale+ MPSoC
Cortex-R5 toolchains and options. Where options are listed,
you need to specify them only if you use the toolchain gcc
and
g++
commands directly instead of invoking sds++
.
Usage | Description |
---|---|
Zynq UltraScale+ MPSoC Arm bare-metal compiler and linker options | -mcpu=cortex-r5 -DARMR5 -mfloat-abi=hard
-mfpu=vfpv3-d16 |
Zynq UltraScale+ MPSoC Arm bare-metal linker options | -Wl,--build-id=none |
Zynq UltraScale+ MPSoC Arm bare-metal compiler | ${SDX_install}/SDK/2019.1/gnu/armr5/lin/gcc-arm-none-eabi/bin Toolchain prefix: gcc executable: g++ executable: |
Zynq UltraScale+ MPSoC SDSoC bare-metal software (lib, include) | ${SDX_install}/SDK/2019.1/gnu/armr5/lin/gcc-arm-none-eabi |
sds++
to compile Zynq-7000 source
files, be aware that SDSoC tools that are processing and
analyzing source files issue errors if they contain NEON instrinsics. If hardware accelerator (or
caller) source files contain NEON intrinsics, guard them using the __SDSCC__
and __SDSVHLS__
macros.For source files that do not contain hardware accelerators or callers but do
use NEON intrinsics, you can either compile them directly using the GNU toolchain and link the
objects with sds++
, or you can add the sds++
command line option -mno-ir
for these source
files. This option prevents clang-based tools from being invoked to create an intermediate
representation (IR) used in analysis. You are programmatically aware that they are not required
(such as no accelerators or callers).