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fuchsia / third_party / qemu / refs/heads/upstream/stable-8.1 / . / target / hexagon / gen_helper_funcs.py
blob: ce21d3b688ed695cdb2f49775202775526aa5d5b [file] [log] [blame]
#!/usr/bin/env python3
##
## Copyright(c) 2019-2023 Qualcomm Innovation Center, Inc. All Rights Reserved.
##
## This program 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 2 of the License, or
## (at your option) any later version.
##
## This program 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 this program; if not, see <http://www.gnu.org/licenses/>.
##
import sys
import re
import string
import hex_common
##
## Helpers for gen_helper_function
##
def gen_decl_ea(f):
f.write(" uint32_t EA;\n")
def gen_helper_return_type(f, regtype, regid, regno):
if regno > 1:
f.write(", ")
f.write("int32_t")
def gen_helper_return_type_pair(f, regtype, regid, regno):
if regno > 1:
f.write(", ")
f.write("int64_t")
def gen_helper_arg(f, regtype, regid, regno):
if regno > 0:
f.write(", ")
f.write(f"int32_t {regtype}{regid}V")
def gen_helper_arg_new(f, regtype, regid, regno):
if regno >= 0:
f.write(", ")
f.write(f"int32_t {regtype}{regid}N")
def gen_helper_arg_pair(f, regtype, regid, regno):
if regno >= 0:
f.write(", ")
f.write(f"int64_t {regtype}{regid}V")
def gen_helper_arg_ext(f, regtype, regid, regno):
if regno > 0:
f.write(", ")
f.write(f"void *{regtype}{regid}V_void")
def gen_helper_arg_ext_pair(f, regtype, regid, regno):
if regno > 0:
f.write(", ")
f.write(f"void *{regtype}{regid}V_void")
def gen_helper_arg_opn(f, regtype, regid, i, tag):
if hex_common.is_pair(regid):
if hex_common.is_hvx_reg(regtype):
gen_helper_arg_ext_pair(f, regtype, regid, i)
else:
gen_helper_arg_pair(f, regtype, regid, i)
elif hex_common.is_single(regid):
if hex_common.is_old_val(regtype, regid, tag):
if hex_common.is_hvx_reg(regtype):
gen_helper_arg_ext(f, regtype, regid, i)
else:
gen_helper_arg(f, regtype, regid, i)
elif hex_common.is_new_val(regtype, regid, tag):
gen_helper_arg_new(f, regtype, regid, i)
else:
hex_common.bad_register(regtype, regid)
else:
hex_common.bad_register(regtype, regid)
def gen_helper_arg_imm(f, immlett):
f.write(f", int32_t {hex_common.imm_name(immlett)}")
def gen_helper_dest_decl(f, regtype, regid, regno, subfield=""):
f.write(f" int32_t {regtype}{regid}V{subfield} = 0;\n")
def gen_helper_dest_decl_pair(f, regtype, regid, regno, subfield=""):
f.write(f" int64_t {regtype}{regid}V{subfield} = 0;\n")
def gen_helper_dest_decl_ext(f, regtype, regid):
if regtype == "Q":
f.write(
f" /* {regtype}{regid}V is *(MMQReg *)" f"({regtype}{regid}V_void) */\n"
)
else:
f.write(
f" /* {regtype}{regid}V is *(MMVector *)"
f"({regtype}{regid}V_void) */\n"
)
def gen_helper_dest_decl_ext_pair(f, regtype, regid, regno):
f.write(
f" /* {regtype}{regid}V is *(MMVectorPair *))"
f"{regtype}{regid}V_void) */\n"
)
def gen_helper_dest_decl_opn(f, regtype, regid, i):
if hex_common.is_pair(regid):
if hex_common.is_hvx_reg(regtype):
gen_helper_dest_decl_ext_pair(f, regtype, regid, i)
else:
gen_helper_dest_decl_pair(f, regtype, regid, i)
elif hex_common.is_single(regid):
if hex_common.is_hvx_reg(regtype):
gen_helper_dest_decl_ext(f, regtype, regid)
else:
gen_helper_dest_decl(f, regtype, regid, i)
else:
hex_common.bad_register(regtype, regid)
def gen_helper_src_var_ext(f, regtype, regid):
if regtype == "Q":
f.write(
f" /* {regtype}{regid}V is *(MMQReg *)" f"({regtype}{regid}V_void) */\n"
)
else:
f.write(
f" /* {regtype}{regid}V is *(MMVector *)"
f"({regtype}{regid}V_void) */\n"
)
def gen_helper_src_var_ext_pair(f, regtype, regid, regno):
f.write(
f" /* {regtype}{regid}V{regno} is *(MMVectorPair *)"
f"({regtype}{regid}V{regno}_void) */\n"
)
def gen_helper_return(f, regtype, regid, regno):
f.write(f" return {regtype}{regid}V;\n")
def gen_helper_return_pair(f, regtype, regid, regno):
f.write(f" return {regtype}{regid}V;\n")
def gen_helper_dst_write_ext(f, regtype, regid):
return
def gen_helper_dst_write_ext_pair(f, regtype, regid):
return
def gen_helper_return_opn(f, regtype, regid, i):
if hex_common.is_pair(regid):
if hex_common.is_hvx_reg(regtype):
gen_helper_dst_write_ext_pair(f, regtype, regid)
else:
gen_helper_return_pair(f, regtype, regid, i)
elif hex_common.is_single(regid):
if hex_common.is_hvx_reg(regtype):
gen_helper_dst_write_ext(f, regtype, regid)
else:
gen_helper_return(f, regtype, regid, i)
else:
hex_common.bad_register(regtype, regid)
##
## Generate the TCG code to call the helper
## For A2_add: Rd32=add(Rs32,Rt32), { RdV=RsV+RtV;}
## We produce:
## int32_t HELPER(A2_add)(CPUHexagonState *env, int32_t RsV, int32_t RtV)
## {
## uint32_t slot __attribute__(unused)) = 4;
## int32_t RdV = 0;
## { RdV=RsV+RtV;}
## COUNT_HELPER(A2_add);
## return RdV;
## }
##
def gen_helper_function(f, tag, tagregs, tagimms):
regs = tagregs[tag]
imms = tagimms[tag]
numresults = 0
numscalarresults = 0
numscalarreadwrite = 0
for regtype, regid in regs:
if hex_common.is_written(regid):
numresults += 1
if hex_common.is_scalar_reg(regtype):
numscalarresults += 1
if hex_common.is_readwrite(regid):
if hex_common.is_scalar_reg(regtype):
numscalarreadwrite += 1
if numscalarresults > 1:
## The helper is bogus when there is more than one result
f.write(
f"void HELPER({tag})(CPUHexagonState *env) " f"{{ BOGUS_HELPER({tag}); }}\n"
)
else:
## The return type of the function is the type of the destination
## register (if scalar)
i = 0
for regtype, regid in regs:
if hex_common.is_written(regid):
if hex_common.is_pair(regid):
if hex_common.is_hvx_reg(regtype):
continue
else:
gen_helper_return_type_pair(f, regtype, regid, i)
elif hex_common.is_single(regid):
if hex_common.is_hvx_reg(regtype):
continue
else:
gen_helper_return_type(f, regtype, regid, i)
else:
hex_common.bad_register(regtype, regid)
i += 1
if numscalarresults == 0:
f.write("void")
f.write(f" HELPER({tag})(CPUHexagonState *env")
## Arguments include the vector destination operands
i = 1
for regtype, regid in regs:
if hex_common.is_written(regid):
if hex_common.is_pair(regid):
if hex_common.is_hvx_reg(regtype):
gen_helper_arg_ext_pair(f, regtype, regid, i)
else:
continue
elif hex_common.is_single(regid):
if hex_common.is_hvx_reg(regtype):
gen_helper_arg_ext(f, regtype, regid, i)
else:
# This is the return value of the function
continue
else:
hex_common.bad_register(regtype, regid)
i += 1
## For conditional instructions, we pass in the destination register
if "A_CONDEXEC" in hex_common.attribdict[tag]:
for regtype, regid in regs:
if hex_common.is_writeonly(regid) and not hex_common.is_hvx_reg(
regtype
):
gen_helper_arg_opn(f, regtype, regid, i, tag)
i += 1
## Arguments to the helper function are the source regs and immediates
for regtype, regid in regs:
if hex_common.is_read(regid):
if hex_common.is_hvx_reg(regtype) and hex_common.is_readwrite(regid):
continue
gen_helper_arg_opn(f, regtype, regid, i, tag)
i += 1
for immlett, bits, immshift in imms:
gen_helper_arg_imm(f, immlett)
i += 1
if hex_common.need_pkt_has_multi_cof(tag):
f.write(", uint32_t pkt_has_multi_cof")
if (hex_common.need_pkt_need_commit(tag)):
f.write(", uint32_t pkt_need_commit")
if hex_common.need_PC(tag):
if i > 0:
f.write(", ")
f.write("target_ulong PC")
i += 1
if hex_common.helper_needs_next_PC(tag):
if i > 0:
f.write(", ")
f.write("target_ulong next_PC")
i += 1
if hex_common.need_slot(tag):
if i > 0:
f.write(", ")
f.write("uint32_t slotval")
i += 1
if hex_common.need_part1(tag):
if i > 0:
f.write(", ")
f.write("uint32_t part1")
f.write(")\n{\n")
if hex_common.need_ea(tag):
gen_decl_ea(f)
## Declare the return variable
i = 0
if "A_CONDEXEC" not in hex_common.attribdict[tag]:
for regtype, regid in regs:
if hex_common.is_writeonly(regid):
gen_helper_dest_decl_opn(f, regtype, regid, i)
i += 1
for regtype, regid in regs:
if hex_common.is_read(regid):
if hex_common.is_pair(regid):
if hex_common.is_hvx_reg(regtype):
gen_helper_src_var_ext_pair(f, regtype, regid, i)
elif hex_common.is_single(regid):
if hex_common.is_hvx_reg(regtype):
gen_helper_src_var_ext(f, regtype, regid)
else:
hex_common.bad_register(regtype, regid)
if hex_common.need_slot(tag):
if "A_LOAD" in hex_common.attribdict[tag]:
f.write(" bool pkt_has_store_s1 = slotval & 0x1;\n")
f.write(" uint32_t slot = slotval >> 1;\n")
if "A_FPOP" in hex_common.attribdict[tag]:
f.write(" arch_fpop_start(env);\n")
f.write(f" {hex_common.semdict[tag]}\n")
if "A_FPOP" in hex_common.attribdict[tag]:
f.write(" arch_fpop_end(env);\n")
## Save/return the return variable
for regtype, regid in regs:
if hex_common.is_written(regid):
gen_helper_return_opn(f, regtype, regid, i)
f.write("}\n\n")
## End of the helper definition
def main():
hex_common.read_semantics_file(sys.argv[1])
hex_common.read_attribs_file(sys.argv[2])
hex_common.read_overrides_file(sys.argv[3])
hex_common.read_overrides_file(sys.argv[4])
## Whether or not idef-parser is enabled is
## determined by the number of arguments to
## this script:
##
## 5 args. -> not enabled,
## 6 args. -> idef-parser enabled.
##
## The 6:th arg. then holds a list of the successfully
## parsed instructions.
is_idef_parser_enabled = len(sys.argv) > 6
if is_idef_parser_enabled:
hex_common.read_idef_parser_enabled_file(sys.argv[5])
hex_common.calculate_attribs()
tagregs = hex_common.get_tagregs()
tagimms = hex_common.get_tagimms()
output_file = sys.argv[-1]
with open(output_file, "w") as f:
for tag in hex_common.tags:
## Skip the priv instructions
if "A_PRIV" in hex_common.attribdict[tag]:
continue
## Skip the guest instructions
if "A_GUEST" in hex_common.attribdict[tag]:
continue
## Skip the diag instructions
if tag == "Y6_diag":
continue
if tag == "Y6_diag0":
continue
if tag == "Y6_diag1":
continue
if hex_common.skip_qemu_helper(tag):
continue
if hex_common.is_idef_parser_enabled(tag):
continue
gen_helper_function(f, tag, tagregs, tagimms)
if __name__ == "__main__":
main()