/* Build device-specs for AVR 8-bit microcontrollers.
Copyright (C) 1998-2024 Free Software Foundation, Inc.
Contributed by Joern Rennecke
This file is part of GCC.
GCC is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3, or (at your option)
any later version.
GCC is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with GCC; see the file COPYING3. If not see
. */
#include
#include
#include
#define IN_TARGET_CODE 1
#include "config.h"
#define IN_GEN_AVR_MMCU_TEXI
#include "avr-devices.cc"
// Get rid of "defaults.h". We just need tm.h for `WITH_AVRLIBC' and
// and `WITH_RTEMS'.
#define GCC_DEFAULTS_H
#include "tm.h"
// Mimic the include order as specified in config.gcc::tm_file.
#include "specs.h"
#if defined (WITH_AVRLIBC)
#include "avrlibc.h"
#endif
#define SPECFILE_DOC_URL \
"https://gcc.gnu.org/onlinedocs/gcc/Spec-Files.html"
#define SPECFILE_USAGE_URL \
"https://gcc.gnu.org/gcc-5/changes.html"
#define WIKI_URL \
"https://gcc.gnu.org/wiki/avr-gcc#spec-files"
static const char header[] =
"#\n"
"# Generated by : ./gcc/config/avr/gen-avr-mmcu-specs.cc\n"
"# Generated from : ./gcc/config/gcc.cc\n"
"# ./gcc/config/avr/specs.h\n"
#if defined (WITH_AVRLIBC)
"# ./gcc/config/avr/avrlibc.h\n"
#endif
"# Used by : avr-gcc compiler driver\n"
"# Used for : building command options for sub-processes\n"
"#\n"
"# See <" SPECFILE_DOC_URL ">\n"
"# for a documentation of spec files.\n"
"\n";
static const char help_copy_paste[] =
"# If you intend to use an existing device specs file as a starting point\n"
"# for a new device spec file, make sure you are copying from a specs file\n"
"# for a device from the same or compatible:\n"
"# compiler version, compiler vendor, core architecture, SP width,\n"
"# short-calls and FLMAP.\n"
"# Otherwise, errors and wrong or sub-optimal code may likely occur.\n"
"# See <" WIKI_URL ">\n"
"# and <" SPECFILE_USAGE_URL "> for a description\n"
"# of how to use such own spec files.\n";
#if defined (WITH_AVRLIBC)
static const char help_dev_lib_name[] =
"# AVR-LibC's avr/io.h uses the device specifying macro to determine\n"
"# the name of the device header. For example, -mmcu=atmega8a triggers\n"
"# the definition of __AVR_ATmega8A__ and avr/io.h includes the device\n"
"# header 'iom8a.h' by means of:\n"
"#\n"
"# ...\n"
"# #elif defined (__AVR_ATmega8A__)\n"
"# # include \n"
"# #elif ...\n"
"# \n"
"# If no device macro is defined, AVR-LibC uses __AVR_DEV_LIB_NAME__\n"
"# as fallback to determine the name of the device header as\n"
"#\n"
"# \"avr/io\" + __AVR_DEV_LIB_NAME__ + \".h\"\n"
"#\n"
"# If you provide your own specs file for a device not yet known to\n"
"# AVR-LibC, you can now define the hook macro __AVR_DEV_LIB_NAME__\n"
"# as needed so that\n"
"#\n"
"# #include \n"
"#\n"
"# will include the desired device header. For ATmega8A the supplement\n"
"# to *cpp_avrlibc would read\n"
"#\n"
"# -D__AVR_DEV_LIB_NAME__=m8a\n"
"\n";
#endif // WITH_AVRLIBC
#ifdef HAVE_LD_AVR_AVRXMEGA2_FLMAP
static const bool have_avrxmega2_flmap = true;
#else
static const bool have_avrxmega2_flmap = false;
#endif
#ifdef HAVE_LD_AVR_AVRXMEGA4_FLMAP
static const bool have_avrxmega4_flmap = true;
#else
static const bool have_avrxmega4_flmap = false;
#endif
#ifdef HAVE_LD_AVR_AVRXMEGA3_RODATA_IN_FLASH
static const bool have_avrxmega3_rodata_in_flash = true;
#else
static const bool have_avrxmega3_rodata_in_flash = false;
#endif
struct McuInfo
{
enum avr_arch_id arch_id;
const avr_arch_t *arch;
bool is_arch, is_device;
bool flmap, have_flmap2, have_flmap4, have_flmap;
bool rodata_in_flash;
// Device name as used by the vendor, extracted from "__AVR___".
char mcu_Name[50] = { 0 };
McuInfo (const avr_mcu_t *mcu)
: arch_id (mcu->arch_id), arch (& avr_arch_types[arch_id]),
is_arch (mcu->macro == NULL), is_device (! is_arch),
flmap (mcu->dev_attribute & AVR_ISA_FLMAP),
have_flmap2 (have_avrxmega2_flmap && arch_id == ARCH_AVRXMEGA2),
have_flmap4 (have_avrxmega4_flmap && arch_id == ARCH_AVRXMEGA4),
have_flmap (flmap && (have_flmap2 || have_flmap4)),
rodata_in_flash (arch_id == ARCH_AVRTINY
|| (arch_id == ARCH_AVRXMEGA3
&& have_avrxmega3_rodata_in_flash))
{
if (is_device)
snprintf (mcu_Name, 1 + strlen (mcu->macro) - strlen ("__AVR_" "__"),
"%s", mcu->macro + strlen ("__AVR_"));
}
};
static void
diagnose_mrodata_in_ram (FILE *f, const char *spec, const avr_mcu_t *mcu,
const McuInfo &mi)
{
fprintf (f, "%s:\n", spec);
if (mi.rodata_in_flash && mi.is_arch)
fprintf (f, "\t%%{mrodata-in-ram: %%e-mrodata-in-ram is not supported"
" for %s}", mcu->name);
else if (mi.rodata_in_flash)
fprintf (f, "\t%%{mrodata-in-ram: %%e-mrodata-in-ram is not supported"
" for %s (arch=%s)}", mi.mcu_Name, mi.arch->name);
else if (mi.is_arch)
{
if (! mi.have_flmap2 && ! mi.have_flmap4)
fprintf (f, "\t%%{mno-rodata-in-ram: %%e-mno-rodata-in-ram is not"
" supported for %s}", mcu->name);
}
else if (! mi.have_flmap)
fprintf (f, "\t%%{mno-rodata-in-ram: %%e-mno-rodata-in-ram is not supported"
" for %s (arch=%s)}", mi.mcu_Name, mi.arch->name);
fprintf (f, "\n\n");
}
static void
print_mcu (const avr_mcu_t *mcu, const McuInfo &mi)
{
const char *sp8_spec;
const char *rcall_spec;
const avr_mcu_t *arch_mcu;
for (arch_mcu = mcu; arch_mcu->macro; )
arch_mcu--;
if (arch_mcu->arch_id != mi.arch_id)
exit (EXIT_FAILURE);
char name[100];
if (snprintf (name, sizeof name, "specs-%s", mcu->name) >= (int) sizeof name)
exit (EXIT_FAILURE);
FILE *f = fopen (name ,"w");
bool absdata = (mcu->dev_attribute & AVR_ISA_LDS) != 0;
bool errata_skip = (mcu->dev_attribute & AVR_ERRATA_SKIP) != 0;
bool rmw = (mcu->dev_attribute & AVR_ISA_RMW) != 0;
bool sp8 = (mcu->dev_attribute & AVR_SHORT_SP) != 0;
bool rcall = (mcu->dev_attribute & AVR_ISA_RCALL);
int rodata_pm_offset = 0;
int pm_base_address = 0;
if (mi.arch->flash_pm_offset
&& mcu->flash_pm_offset
&& mcu->flash_pm_offset != mi.arch->flash_pm_offset)
{
rodata_pm_offset = mcu->flash_pm_offset;
}
if (mi.arch->flash_pm_offset)
{
pm_base_address = mcu->flash_pm_offset
? mcu->flash_pm_offset
: mi.arch->flash_pm_offset;
}
if (mi.is_arch
&& (ARCH_AVR2 == mi.arch_id
|| ARCH_AVR25 == mi.arch_id))
{
// Leave "avr2" and "avr25" alone. These two architectures are
// the only ones that mix devices with 8-bit SP and 16-bit SP.
sp8_spec = "";
}
else
{
sp8_spec = sp8 ? "-msp8" :"%name);
else
fprintf (f, "device %s (core %s, %d-bit SP%s%s)\n", mi.mcu_Name,
mi.arch->name, sp8 ? 8 : 16, rcall ? ", short-calls" : "",
mi.have_flmap ? ", FLMAP" : "");
fprintf (f, "%s\n", header);
if (mi.is_device)
fprintf (f, "%s\n", help_copy_paste);
#if defined (WITH_AVRLIBC)
// AVR-LibC specific. See avrlibc.h for the specs using them as subspecs.
if (mi.is_device)
{
fprintf (f, "*avrlibc_startfile:\n");
fprintf (f, "\tcrt%s.o%%s", mcu->name);
fprintf (f, "\n\n");
fprintf (f, "*avrlibc_devicelib:\n");
fprintf (f, "\t%%{!nodevicelib:-l%s}", mcu->name);
fprintf (f, "\n\n");
}
#endif // WITH_AVRLIBC
// Diagnose usage of -m[no-]rodata-in-ram.
diagnose_mrodata_in_ram (f, "*check_rodata_in_ram", mcu, mi);
// avr-gcc specific specs for the compilation / the compiler proper.
int n_flash = 1 + (mcu->flash_size - 1) / 0x10000;
fprintf (f, "*cc1_n_flash:\n"
"\t%%{!mn-flash=*:-mn-flash=%d}\n\n", n_flash);
fprintf (f, "*cc1_rmw:\n%s\n\n", rmw
? "\t%{!mno-rmw: -mrmw}"
: "\t%{mrmw}");
fprintf (f, "*cc1_errata_skip:\n%s\n\n", errata_skip
? "\t%{!mno-skip-bug: -mskip-bug}"
: "\t%{!mskip-bug: -mno-skip-bug}");
fprintf (f, "*cc1_absdata:\n%s\n\n", absdata
? "\t%{!mno-absdata: -mabsdata}"
: "\t%{mabsdata}");
// -m[no-]rodata-in-ram basically affects linking, but sanity-check early.
fprintf (f, "*cc1_rodata_in_ram:\n\t%%(check_rodata_in_ram)\n\n");
// avr-gcc specific specs for assembling / the assembler.
fprintf (f, "*asm_arch:\n\t-mmcu=%s\n\n", mi.arch->name);
#ifdef HAVE_AS_AVR_MLINK_RELAX_OPTION
fprintf (f, "*asm_relax:\n\t%s\n\n", ASM_RELAX_SPEC);
#endif // have avr-as --mlink-relax
#ifdef HAVE_AS_AVR_MRMW_OPTION
fprintf (f, "*asm_rmw:\n%s\n\n", rmw
? "\t%{!mno-rmw: -mrmw}"
: "\t%{mrmw}");
#endif // have avr-as -mrmw
#ifdef HAVE_AS_AVR_MGCCISR_OPTION
fprintf (f, "*asm_gccisr:\n%s\n\n",
"\t%{!mno-gas-isr-prologues: -mgcc-isr}");
#endif // have avr-as -mgcc-isr
fprintf (f, "*asm_errata_skip:\n%s\n\n", errata_skip
? "\t%{mno-skip-bug}"
: "\t%{!mskip-bug: -mno-skip-bug}");
// avr-specific specs for linking / the linker.
int wrap_k =
mcu->flash_size == 0x2000 ? 8
: mcu->flash_size == 0x4000 ? 16
: mcu->flash_size == 0x8000 ? 32
: mcu->flash_size == 0x10000 ? 64
: 0;
fprintf (f, "*link_pmem_wrap:\n");
if (wrap_k == 8)
fprintf (f, "\t%%{!mno-pmem-wrap-around: --pmem-wrap-around=8k}");
else if (wrap_k > 8)
fprintf (f, "\t%%{mpmem-wrap-around: --pmem-wrap-around=%dk}", wrap_k);
fprintf (f, "\n\n");
fprintf (f, "*link_relax:\n\t%s\n\n", LINK_RELAX_SPEC);
fprintf (f, "*link_arch:\n\t%s", link_arch_spec);
if (mi.is_device
&& rodata_pm_offset)
fprintf (f, " --defsym=__RODATA_PM_OFFSET__=0x%x", rodata_pm_offset);
fprintf (f, "\n\n");
if (mi.is_device)
{
fprintf (f, "*link_data_start:\n");
if (mcu->data_section_start
!= mi.arch->default_data_section_start)
fprintf (f, "\t%%{!Tdata:-Tdata 0x%lX}",
0x800000UL + mcu->data_section_start);
fprintf (f, "\n\n");
fprintf (f, "*link_text_start:\n");
if (mcu->text_section_start != 0x0)
fprintf (f, "\t%%{!Ttext:-Ttext 0x%lX}", 0UL + mcu->text_section_start);
fprintf (f, "\n\n");
}
// -m[no-]rodata-in-ram affects linking. Sanity check its usage.
fprintf (f, "*link_rodata_in_ram:\n\t%%(check_rodata_in_ram)");
if (mi.is_device && mi.have_flmap)
fprintf (f, " %%{!mrodata-in-ram:-u __do_flmap_init}");
fprintf (f, "\n\n");
// Specs known to GCC.
if (mi.is_device)
{
fprintf (f, "*self_spec:\n");
fprintf (f, "\t%%name);
fprintf (f, "%s ", flmap_spec);
fprintf (f, "%s ", rcall_spec);
fprintf (f, "%s\n\n", sp8_spec);
#if defined (WITH_AVRLIBC)
fprintf (f, "%s\n", help_dev_lib_name);
fprintf (f, "*cpp_avrlibc:\n");
fprintf (f, "\t-D__AVR_DEVICE_NAME__=%s", mcu->name);
fprintf (f, "\n\n");
#endif // WITH_AVRLIBC
fprintf (f, "*cpp_mcu:\n");
fprintf (f, "\t-D%s", mcu->macro);
if (pm_base_address)
{
fprintf (f, " -U__AVR_PM_BASE_ADDRESS__");
fprintf (f, " -D__AVR_PM_BASE_ADDRESS__=0x%x", pm_base_address);
}
if (mi.have_flmap)
fprintf (f, " -D__AVR_HAVE_FLMAP__");
fprintf (f, "\n\n"); // *cpp_mcu
fprintf (f, "*cpp_rodata_in_ram:\n\t-D__AVR_RODATA_IN_RAM__=");
if (mi.rodata_in_flash)
fprintf (f, "0");
else if (! mi.have_flmap)
fprintf (f, "1");
else
fprintf (f, "%%{!mrodata-in-ram:%%{!mno-rodata-in-ram:0}}"
"%%{mrodata-in-ram:1}" "%%{mno-rodata-in-ram:0}");
fprintf (f, "\n\n");
fprintf (f, "*cpp:\n");
fprintf (f, "\t%%(cpp_mcu) %%(cpp_rodata_in_ram)");
#if defined (WITH_AVRLIBC)
fprintf (f, " %%(cpp_avrlibc)");
#endif // WITH_AVRLIBC
fprintf (f, "\n\n");
}
fprintf (f, "# End of file\n");
fclose (f);
}
int main (void)
{
for (const avr_mcu_t *mcu = avr_mcu_types; mcu->name; mcu++)
print_mcu (mcu, McuInfo (mcu));
return EXIT_SUCCESS;
}