Vault 7: Projects

This publication series is about specific projects related to the Vault 7 main publication.

MPLAB
®
XC16 C Compiler Users Guide
DS50002071C-page 108 2012-2013 Microchip Technology Inc.
xc16-gcc -mcpu=30f2010 -o app2010.out -T p30f2010.gld app2010.c
The -o command-line option names the output executable file, and the -T option gives
the linker script name for the dsPIC30F2010 part. If p30f2010.gld is not found in the
current directory, the linker searches in its known library paths. The default search path
includes all locations of preinstalled libraries and linker scripts.
You should copy the appropriate linker script file (supplied with the compiler) into your
project directory before any project-specific modifications are made.
6.4 STACK
The 16-bit devices use what is referred to in this users guide as a software stack. This
is the typical stack arrangement employed by most computers and is ordinary data
memory accessed by a push-and-pop type instruction and a stack pointer register. The
term hardware stack is used to describe the stack employed by Microchip 8-bit
devices, which is only used for storing function return addresses.
The 16-bit devices dedicate register W15 for use as a software Stack Pointer. All
processor stack operations, including function calls, interrupts and exceptions, use the
software stack. The stack grows upward, towards higher memory addresses.
The dsPIC DSC device also supports stack overflow detection. If the Stack Pointer
Limit register, SPLIM, is initialized, the device will test for overflow on all stack opera-
tions. If an overflow should occur, the processor will initiate a stack error exception. By
default, this will result in a processor Reset. Applications may also install a stack error
exception handler by defining an interrupt function named _StackError. See Chap-
ter 14. Interrupts for details.
The C run-time startup module initializes the Stack Pointer (W15) and the Stack Pointer
Limit register during the startup and initialization sequence. The initial values are
normally provided by the linker, which allocates the largest stack possible from unused
data memory. The location of the stack is reported in the link map output file.
Applications can ensure that at least a minimum-sized stack is available with the
--stack linker command-line option. See the MPLAB XC16 Assembler, Linker and
Utilities Users Guide (DS52106) for details.
Alternatively, a stack of specific size may be allocated with a user-defined section from
an assembly source file. In the following example, 0x100 bytes of data memory are
reserved for the stack:
.section *,data,stack
.space 0x100
The linker will allocate an appropriately sized section and initialize __SP_init and
__SPLIM_init so that the run-time startup code can properly initialize the stack. Note
that since this is a normal assembly code section, attributes such as address may be
used to further define the stack. Please see the MPLAB XC16 Assembler, Linker and
Utilities Users Guide (DS52106) for more information.

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