DBT-RISE/DBT-RISE-TGC
9
0
Fork 0
Code Issues 1 Pull Requests 1 Projects Releases Wiki Activity

Compare commits

base: DBT-RISE:feature/interpreter
Branches Tags
DBT-RISE:main DBT-RISE:develop DBT-RISE:featture/interp_instr_cache DBT-RISE:feature/privilege_refactor DBT-RISE:feature/htif DBT-RISE:feature/eve_checkin DBT-RISE:feature/iss_factory DBT-RISE:feature/core_factory DBT-RISE:Trace_enhancement DBT-RISE:feature/reduced_output DBT-RISE:msvc_compat DBT-RISE:hotfix/latest_scc DBT-RISE:feature/interpreter
...
compare: DBT-RISE:d43b35949e60c45e45ec43af1977478d0f93869d
Branches Tags
DBT-RISE:develop DBT-RISE:featture/interp_instr_cache DBT-RISE:feature/privilege_refactor DBT-RISE:feature/htif DBT-RISE:feature/eve_checkin DBT-RISE:main DBT-RISE:feature/iss_factory DBT-RISE:feature/core_factory DBT-RISE:Trace_enhancement DBT-RISE:feature/reduced_output DBT-RISE:msvc_compat DBT-RISE:hotfix/latest_scc DBT-RISE:feature/interpreter

22 Commits
feature/in ... d43b35949e

Author SHA1 Message Date
eyck
d43b35949e fix CMakeList.txt so that it builds without platform and external libs 2020-12-23 16:24:10 +00:00
Stas
be49b8b545 Relative path to a submodule 2020-12-10 15:32:03 +01:00
Stanislaw Kaushanski
43488676dd Update TGF naming convention 2020-09-11 10:45:44 +02:00
Stanislaw Kaushanski
f3d578f050 Remove 64bit support 2020-09-07 14:30:19 +02:00
Stanislaw Kaushanski
293c396a0d update core wrapper: remove virtual memory support 2020-09-07 13:29:45 +02:00
Stanislaw Kaushanski
6f3963a473 Strip down privileged modes. Only machine mode is supported 2020-09-07 11:54:45 +02:00
Stanislaw Kaushanski
969b408288 Implement MHARTID register 2020-09-04 15:37:21 +02:00
Stanislaw Kaushanski
886b8f5716 TGF02 is a default core 2020-08-31 14:20:13 +02:00
Stanislaw Kaushanski
c2c8fb5ca9 update README 2020-08-24 15:14:49 +02:00
Stanislaw Kaushanski
9754e3953f Generate and integrate TGF cores in Ecosystem-VP. Remove obsolete cores 2020-08-24 15:01:54 +02:00
Stanislaw Kaushanski
03172e352d move CoreDSL instraction set description files into a dedicated repository CoreDSL-Instruction-Set-Description 2020-08-21 15:57:01 +02:00
Stanislaw Kaushanski
8fce0c4759 Generate TGF01 and TGF02 cores 2020-08-20 17:29:36 +02:00
eyck
18976e2ce4 adapt to newer gdb protocol 2020-06-22 08:45:12 +02:00
eyck
71b976811b add backend selection 2020-06-18 09:58:43 +02:00
eyck
edeff7add8 update log macros 2020-06-18 07:38:56 +02:00
eyck
e902936931 make interpreter default 2020-06-18 07:22:50 +02:00
eyck
55450f4900 [WIP] update dependencies in core desc 2020-06-18 06:18:59 +02:00
eyck
c619194465 [WIP] rework generator 2020-06-05 07:25:40 +02:00
eyck
abcfb75011 [WIP] 2020-05-31 16:41:04 +02:00
eyck
10797a473d modernize build system and cleanup dependencies 2020-05-30 14:16:10 +02:00
eyck
0ff6ccf9e2 get all compile clean 2020-05-30 11:27:44 +02:00
eyck
97a8ab1680 Merge branch 'feature/interpreter' into develop 2020-05-29 08:54:38 +02:00
55 changed files with 7989 additions and 35288 deletions
Expand all files Collapse all files

3
.gitmodules vendored Normal file
View File

@@ -0,0 +1,3 @@
[submodule "gen_input/CoreDSL-Instruction-Set-Description"]
path = gen_input/CoreDSL-Instruction-Set-Description
url = ../CoreDSL-Instruction-Set-Description.git

165
CMakeLists.txt
View File

@@ -1,135 +1,110 @@
cmake_minimum_required(VERSION 3.12) cmake_minimum_required(VERSION 3.12)
set(CMAKE_MODULE_PATH ${CMAKE_MODULE_PATH} ${CMAKE_CURRENT_SOURCE_DIR}/../cmake) # main (top) cmake dir
set(CMAKE_MODULE_PATH ${CMAKE_MODULE_PATH} ${CMAKE_CURRENT_SOURCE_DIR}/cmake) # project specific cmake dir
# CMake useful variables project("tgfs" VERSION 1.0.0)
set(CMAKE_RUNTIME_OUTPUT_DIRECTORY "${CMAKE_BINARY_DIR}/bin")
set(CMAKE_ARCHIVE_OUTPUT_DIRECTORY "${CMAKE_BINARY_DIR}/lib")
set(CMAKE_LIBRARY_OUTPUT_DIRECTORY "${CMAKE_BINARY_DIR}/lib")
# Set the name of your project here include(GNUInstallDirs)
project("riscv")
include(Common)
conan_basic_setup() conan_basic_setup()
find_package(Boost COMPONENTS program_options system thread filesystem REQUIRED) find_package(Boost COMPONENTS program_options system thread filesystem REQUIRED)
if(WITH_LLVM)
# This sets the include directory for the reference project. This is the -I flag in gcc. if(DEFINED ENV{LLVM_HOME})
include_directories( find_path (LLVM_DIR LLVM-Config.cmake $ENV{LLVM_HOME}/lib/cmake/llvm)
${PROJECT_SOURCE_DIR}/incl endif(DEFINED ENV{LLVM_HOME})
${SOFTFLOAT_INCLUDE_DIRS} find_package(LLVM REQUIRED CONFIG)
${LLVM_INCLUDE_DIRS} message(STATUS "Found LLVM ${LLVM_PACKAGE_VERSION}")
) message(STATUS "Using LLVMConfig.cmake in: ${LLVM_DIR}")
add_dependent_subproject(dbt-core) llvm_map_components_to_libnames(llvm_libs support core mcjit x86codegen x86asmparser)
include_directories( endif()
${PROJECT_SOURCE_DIR}/incl
${PROJECT_SOURCE_DIR}/../external/elfio
${PROJECT_SOURCE_DIR}/../external/libGIS
${Boost_INCLUDE_DIRS}
)
#Mac needed variables (adapt for your needs - http://www.cmake.org/Wiki/CMake_RPATH_handling#Mac_OS_X_and_the_RPATH) #Mac needed variables (adapt for your needs - http://www.cmake.org/Wiki/CMake_RPATH_handling#Mac_OS_X_and_the_RPATH)
set(CMAKE_MACOSX_RPATH ON) #set(CMAKE_MACOSX_RPATH ON)
set(CMAKE_SKIP_BUILD_RPATH FALSE) #set(CMAKE_SKIP_BUILD_RPATH FALSE)
set(CMAKE_BUILD_WITH_INSTALL_RPATH FALSE) #set(CMAKE_BUILD_WITH_INSTALL_RPATH FALSE)
set(CMAKE_INSTALL_RPATH "${CMAKE_INSTALL_PREFIX}/lib") #set(CMAKE_INSTALL_RPATH "${CMAKE_INSTALL_PREFIX}/lib")
set(CMAKE_INSTALL_RPATH_USE_LINK_PATH TRUE) #set(CMAKE_INSTALL_RPATH_USE_LINK_PATH TRUE)
add_subdirectory(softfloat) add_subdirectory(softfloat)
# library files # library files
FILE(GLOB RiscVSCHeaders ${CMAKE_CURRENT_SOURCE_DIR}/incl/sysc/*.h ${CMAKE_CURRENT_SOURCE_DIR}/incl/sysc/*/*.h) FILE(GLOB RiscVSCHeaders ${CMAKE_CURRENT_SOURCE_DIR}/incl/sysc/*.h ${CMAKE_CURRENT_SOURCE_DIR}/incl/sysc/*/*.h)
set(LIB_HEADERS ${RiscVSCHeaders} ) set(LIB_HEADERS tgfscVSCHeaders} )
set(LIB_SOURCES set(LIB_SOURCES
#src/iss/rv32gc.cpp src/iss/tgf_b.cpp
src/iss/rv32imac.cpp src/iss/tgf_c.cpp
#src/iss/rv64i.cpp src/vm/fp_functions.cpp
#src/iss/rv64gc.cpp src/vm/tcc/vm_tgf_b.cpp
src/iss/mnrv32.cpp src/vm/tcc/vm_tgf_c.cpp
src/vm/llvm/fp_functions.cpp src/vm/interp/vm_tgf_b.cpp
src/vm/llvm/vm_mnrv32.cpp src/vm/interp/vm_tgf_c.cpp
#src/vm/llvm/vm_rv32gc.cpp
#src/vm/llvm/vm_rv32imac.cpp
#src/vm/llvm/vm_rv64i.cpp
#src/vm/llvm/vm_rv64gc.cpp
src/vm/tcc/vm_mnrv32.cpp
src/vm/interp/vm_mnrv32.cpp
src/plugin/instruction_count.cpp src/plugin/instruction_count.cpp
src/plugin/cycle_estimate.cpp) src/plugin/cycle_estimate.cpp
)
# Define two variables in order not to repeat ourselves. if(WITH_LLVM)
set(LIBRARY_NAME riscv) set(LIB_SOURCES ${LIB_SOURCES}
src/vm/llvm/fp_impl.cpp
src/vm/llvm/vm_tgf_b.cpp
src/vm/llvm/vm_tgf_c.cpp
)
endif()
# Define the library # Define the library
add_library(${LIBRARY_NAME} ${LIB_SOURCES}) add_library(tgfs SHARED ${LIB_SOURCES})
SET(${LIBRARY_NAME} -Wl,-whole-archive -l${LIBRARY_NAME} -Wl,-no-whole-archive) target_compile_options(tgfs PRIVATE -Wno-shift-count-overflow)
target_link_libraries(${LIBRARY_NAME} softfloat dbt-core scc-util) target_include_directories(tgfs PUBLIC incl)
set_target_properties(${LIBRARY_NAME} PROPERTIES target_link_libraries(tgfs PUBLIC softfloat scc-util)
VERSION ${VERSION} # ${VERSION} was defined in the main CMakeLists. target_link_libraries(tgfs PUBLIC -Wl,--whole-archive dbt-core -Wl,--no-whole-archive)
set_target_properties(tgfs PROPERTIES
VERSION ${PROJECT_VERSION}
FRAMEWORK FALSE FRAMEWORK FALSE
PUBLIC_HEADER "${LIB_HEADERS}" # specify the public headers PUBLIC_HEADER "${LIB_HEADERS}" # specify the public headers
) )
if(SystemC_FOUND) if(SystemC_FOUND)
set(SC_LIBRARY_NAME riscv_sc) add_library(tgfs_sc src/sysc/core_complex.cpp)
add_library(${SC_LIBRARY_NAME} src/sysc/core_complex.cpp) target_compile_definitions(tgfs_sc PUBLIC WITH_SYSTEMC)
add_definitions(-DWITH_SYSTEMC) target_include_directories(tgfs_sc PUBLIC ../incl ${SystemC_INCLUDE_DIRS} ${CCI_INCLUDE_DIRS})
include_directories(${SystemC_INCLUDE_DIRS})
include_directories(${CCI_INCLUDE_DIRS})
if(SCV_FOUND) if(SCV_FOUND)
add_definitions(-DWITH_SCV) target_compile_definitions(tgfs_sc PUBLIC WITH_SCV)
include_directories(${SCV_INCLUDE_DIRS}) target_include_directories(tgfs_sc PUBLIC ${SCV_INCLUDE_DIRS})
endif() endif()
target_link_libraries(${SC_LIBRARY_NAME} ${LIBRARY_NAME}) target_link_libraries(tgfs_sc PUBLIC tgfs scc )
target_link_libraries(${SC_LIBRARY_NAME} dbt-core) if(WITH_LLVM)
target_link_libraries(${SC_LIBRARY_NAME} softfloat) target_link_libraries(tgfs_sc PUBLIC ${llvm_libs})
target_link_libraries(${SC_LIBRARY_NAME} scc) endif()
target_link_libraries(${SC_LIBRARY_NAME} external) target_link_libraries(tgfs_sc PUBLIC ${Boost_LIBRARIES} )
target_link_libraries(${SC_LIBRARY_NAME} ${llvm_libs}) set_target_properties(tgfs_sc PROPERTIES
target_link_libraries(${SC_LIBRARY_NAME} ${Boost_LIBRARIES} ) VERSION ${PROJECT_VERSION}
set_target_properties(${SC_LIBRARY_NAME} PROPERTIES
VERSION ${VERSION} # ${VERSION} was defined in the main CMakeLists.
FRAMEWORK FALSE FRAMEWORK FALSE
PUBLIC_HEADER "${LIB_HEADERS}" # specify the public headers PUBLIC_HEADER "${LIB_HEADERS}" # specify the public headers
) )
endif() endif()
project("riscv-sim") project("tgfs-sim")
add_executable(tgfs-sim src/main.cpp)
# This is a make target, so you can do a "make riscv-sc" # This sets the include directory for the reference project. This is the -I flag in gcc.
set(APPLICATION_NAME riscv-sim)
add_executable(${APPLICATION_NAME} src/main.cpp)
if(WITH_LLVM)
target_compile_definitions(tgfs-sim PRIVATE WITH_LLVM)
target_link_libraries(tgfs-sim PUBLIC ${llvm_libs})
endif()
# Links the target exe against the libraries # Links the target exe against the libraries
target_link_libraries(${APPLICATION_NAME} ${LIBRARY_NAME}) target_link_libraries(tgfs-sim tgfs)
target_link_libraries(${APPLICATION_NAME} jsoncpp) target_link_libraries(tgfs-sim jsoncpp)
target_link_libraries(${APPLICATION_NAME} dbt-core) target_link_libraries(tgfs-sim ${Boost_LIBRARIES} )
target_link_libraries(${APPLICATION_NAME} external)
target_link_libraries(${APPLICATION_NAME} ${llvm_libs})
target_link_libraries(${APPLICATION_NAME} ${Boost_LIBRARIES} )
if (Tcmalloc_FOUND) if (Tcmalloc_FOUND)
target_link_libraries(${APPLICATION_NAME} ${Tcmalloc_LIBRARIES}) target_link_libraries(tgfs-sim ${Tcmalloc_LIBRARIES})
endif(Tcmalloc_FOUND) endif(Tcmalloc_FOUND)
# Says how and where to install software install(TARGETS tgfs tgfs-sim
# Targets:
# * <prefix>/lib/<libraries>
# * header location after install: <prefix>/include/<project>/*.h
# * headers can be included by C++ code `#<project>/Bar.hpp>`
install(TARGETS ${LIBRARY_NAME} ${APPLICATION_NAME}
EXPORT ${PROJECT_NAME}Targets # for downstream dependencies EXPORT ${PROJECT_NAME}Targets # for downstream dependencies
ARCHIVE DESTINATION lib COMPONENT libs # static lib ARCHIVE DESTINATION ${CMAKE_INSTALL_LIBDIR} COMPONENT libs # static lib
RUNTIME DESTINATION bin COMPONENT libs # binaries RUNTIME DESTINATION ${CMAKE_INSTALL_BINDIR} COMPONENT libs # binaries
LIBRARY DESTINATION lib COMPONENT libs # shared lib LIBRARY DESTINATION ${CMAKE_INSTALL_LIBDIR} COMPONENT libs # shared lib
FRAMEWORK DESTINATION bin COMPONENT libs # for mac FRAMEWORK DESTINATION ${CMAKE_INSTALL_LIBDIR} COMPONENT libs # for mac
PUBLIC_HEADER DESTINATION incl/${PROJECT_NAME} COMPONENT devel # headers for mac (note the different component -> different package) PUBLIC_HEADER DESTINATION ${CMAKE_INSTALL_INCLUDEDIR}/${PROJECT_NAME} COMPONENT devel # headers for mac (note the different component -> different package)
INCLUDES DESTINATION incl # headers INCLUDES DESTINATION ${CMAKE_INSTALL_INCLUDEDIR} # headers
) )

119
CMakeLists.txt.orig
View File

@@ -1,119 +0,0 @@
cmake_minimum_required(VERSION 3.3)
set(CMAKE_MODULE_PATH ${CMAKE_MODULE_PATH} ${CMAKE_CURRENT_SOURCE_DIR}/cmake ${CMAKE_CURRENT_SOURCE_DIR}/sc-components/cmake)
set(ENABLE_SCV TRUE CACHE BOOL "Enable use of SCV")
set(ENABLE_SHARED TRUE CACHE BOOL "Build shared libraries")
include(GitFunctions)
get_branch_from_git()
# if we are not on master or develop set the submodules to develop
IF(NOT ${GIT_BRANCH} MATCHES "master")
IF(NOT ${GIT_BRANCH} MATCHES "develop")
message(STATUS "main branch is '${GIT_BRANCH}', setting submodules to 'develop'")
set(GIT_BRANCH develop)
endif()
endif()
### set the directory names of the submodules
set(GIT_SUBMODULES elfio libGIS sc-components dbt-core)
set(GIT_SUBMODULE_DIR_sc-components .)
set(GIT_SUBMODULE_DIR_dbt-core .)
### set each submodules's commit or tag that is to be checked out
### (leave empty if you want master)
#set(GIT_SUBMODULE_VERSION_sc-comp 3af6b9836589b082c19d9131c5d0b7afa8ddd7cd)
set(GIT_SUBMODULE_BRANCH_sc-components ${GIT_BRANCH})
set(GIT_SUBMODULE_BRANCH_dbt-core ${GIT_BRANCH})
include(GNUInstallDirs)
include(Submodules)
include(Conan)
#enable_testing()
set(CMAKE_CXX_STANDARD 14)
set(CMAKE_CXX_STANDARD_REQUIRED ON)
set(CMAKE_CXX_EXTENSIONS OFF)
set(CMAKE_POSITION_INDEPENDENT_CODE ON)
include(CheckCXXCompilerFlag)
CHECK_CXX_COMPILER_FLAG("-march=native" COMPILER_SUPPORTS_MARCH_NATIVE)
if(COMPILER_SUPPORTS_MARCH_NATIVE)
if("${CMAKE_BUILD_TYPE}" STREQUAL "")
set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -march=native")
elseif(NOT(${CMAKE_BUILD_TYPE} STREQUAL "RelWithDebInfo"))
set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -march=native")
endif()
endif()
if ("${CMAKE_CXX_COMPILER_ID}" STREQUAL "GNU" OR "${CMAKE_CXX_COMPILER_ID}" STREQUAL "Clang")
set(warnings "-Wall -Wextra -Werror")
#set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -D_GLIBCXX_USE_CXX11_ABI=0")
set(CMAKE_CXX_FLAGS_RELEASE "-O3 -DNDEBUG")
set(CMAKE_C_FLAGS_RELEASE "-O3 -DNDEBUG")
elseif ("${CMAKE_CXX_COMPILER_ID}" STREQUAL "MSVC")
set(warnings "/W4 /WX /EHsc")
endif()
setup_conan()
# This line finds the boost lib and headers.
set(Boost_NO_BOOST_CMAKE ON) # Don't do a find_package in config mode before searching for a regular boost install.
find_package(Boost COMPONENTS program_options system thread filesystem REQUIRED)
if(DEFINED ENV{LLVM_HOME})
find_path (LLVM_DIR LLVM-Config.cmake $ENV{LLVM_HOME}/lib/cmake/llvm)
endif(DEFINED ENV{LLVM_HOME})
find_package(LLVM REQUIRED CONFIG)
message(STATUS "Found LLVM ${LLVM_PACKAGE_VERSION}")
message(STATUS "Using LLVMConfig.cmake in: ${LLVM_DIR}")
llvm_map_components_to_libnames(llvm_libs support core mcjit x86codegen x86asmparser)
find_package(Threads)
find_package(Tcmalloc)
find_package(ZLIB)
find_package(SystemC)
if(SystemC_FOUND)
message(STATUS "SystemC headers at ${SystemC_INCLUDE_DIRS}")
message(STATUS "SystemC library at ${SystemC_LIBRARY_DIRS}")
if(SCV_FOUND)
message(STATUS "SCV headers at ${SCV_INCLUDE_DIRS}")
message(STATUS "SCV library at ${SCV_LIBRARY_DIRS}")
endif(SCV_FOUND)
if(CCI_FOUND)
message(STATUS "CCI headers at ${CCI_INCLUDE_DIRS}")
message(STATUS "CCI library at ${CCI_LIBRARY_DIRS}")
endif()
endif(SystemC_FOUND)
set(PROJECT_3PARTY_DIRS external)
include(clang-format)
set(ENABLE_CLANG_TIDY OFF CACHE BOOL "Add clang-tidy automatically to builds")
if (ENABLE_CLANG_TIDY)
find_program (CLANG_TIDY_EXE NAMES "clang-tidy" PATHS /usr/local/opt/llvm/bin )
if (CLANG_TIDY_EXE)
message(STATUS "clang-tidy found: ${CLANG_TIDY_EXE}")
set(CLANG_TIDY_CHECKS "-*,modernize-*")
set(CMAKE_CXX_CLANG_TIDY "${CLANG_TIDY_EXE};-checks=${CLANG_TIDY_CHECKS};-header-filter='${CMAKE_SOURCE_DIR}/*';-fix"
CACHE STRING "" FORCE)
else()
message(AUTHOR_WARNING "clang-tidy not found!")
set(CMAKE_CXX_CLANG_TIDY "" CACHE STRING "" FORCE) # delete it
endif()
endif()
# Set the version number of your project here (format is MAJOR.MINOR.PATCHLEVEL - e.g. 1.0.0)
set(VERSION_MAJOR "1")
set(VERSION_MINOR "0")
set(VERSION_PATCH "0")
set(VERSION ${VERSION_MAJOR}.${VERSION_MINOR}.${VERSION_PATCH})
add_subdirectory(external)
add_subdirectory(dbt-core)
add_subdirectory(sc-components)
add_subdirectory(softfloat)
GET_DIRECTORY_PROPERTY(SOFTFLOAT_INCLUDE_DIRS DIRECTORY softfloat DEFINITION SOFTFLOAT_INCLUDE_DIRS)
add_subdirectory(riscv)
add_subdirectory(platform)
message(STATUS "Build Type: ${CMAKE_BUILD_TYPE}")

16
README.md
View File

@@ -1,18 +1,16 @@
# DBT-RISE-RISCV # DBT-RISE-TGFS
Core of an instruction set simulator based on DBT-RISE implementing the RISC-V ISA. The project is hosted at https://git.minres.com/DBT-RISE/DBT-RISE-RISCV . Core of an instruction set simulator based on DBT-RISE implementing Minres The Good Folks Series cores. The project is hosted at https://git.minres.com/DBT-RISE/DBT-RISE-TGFS .
This repo contains only the code of the RISC-V ISS and can only be used with the DBT_RISE. A complete VP using this ISS can be found at https://git.minres.com/VP/RISCV-VP which models SiFives FE310 controlling a brushless DC (BLDC) motor. This repo contains only the code of the RISC-V ISS and can only be used with the DBT_RISE. A complete VP using this ISS can be found at https://git.minres.com/VP/Ecosystem-VP ~~which models SiFives FE310 controlling a brushless DC (BLDC) motor~~.
This library provide the infrastructure to build RISC-V ISS. Currently part of the library are the following implementations adhering to version 2.2 of the 'The RISC-V Instruction Set Manual Volume I: User-Level ISA': This library provide the infrastructure to build RISC-V ISS. Currently part of the library are the following implementations adhering to version 2.2 of the 'The RISC-V Instruction Set Manual Volume I: User-Level ISA':
* RV32IMAC * RV32I (TGF-B)
* RV32GC * RV32MIC (TGF-C)
* RC64I
* RV64GC
All pass the respective compliance tests. Along with those ISA implementations there is a wrapper implementing the M/S/U modes inlcuding virtual memory management and CSRs as of privileged spec 1.10. The main.cpp in src allows to build a standalone ISS when integrated into a top-level project. For further information please have a look at [https://git.minres.com/VP/RISCV-VP](https://git.minres.com/VP/RISCV-VP). All pass the respective compliance tests. Along with those ISA implementations there is a wrapper (riscv_hart_m_p.h) implementing the Machine privileged mode as of privileged spec 1.10. The main.cpp in src allows to build a stand-alone ISS when integrated into a top-level project. For further information please have a look at [https://git.minres.com/VP/RISCV-VP](https://git.minres.com/VP/RISCV-VP).
Last but not least an SystemC wrapper is provided which allows easy integration into SystemC based virtual platforms. Last but not least an SystemC wrapper is provided which allows easy integration into SystemC based virtual platforms.
Since DBT-RISE uses a generative approch other needed combinations or custom extension can be generated. For further information please contact [info@minres.com](mailto:info@minres.com). Since DBT-RISE uses a generative approach other needed combinations or custom extension can be generated. For further information please contact [info@minres.com](mailto:info@minres.com).

1
gen_input/CoreDSL-Instruction-Set-Description Submodule

Submodule gen_input/CoreDSL-Instruction-Set-Description added at 3bb3763e92

50
gen_input/RISCVBase.core_desc
View File

@@ -1,50 +0,0 @@
InsructionSet RISCVBase {
constants {
XLEN,
fence:=0,
fencei:=1,
fencevmal:=2,
fencevmau:=3
}
address_spaces {
MEM[8], CSR[XLEN], FENCE[XLEN], RES[8]
}
registers {
[31:0] X[XLEN],
PC[XLEN](is_pc),
alias ZERO[XLEN] is X[0],
alias RA[XLEN] is X[1],
alias SP[XLEN] is X[2],
alias GP[XLEN] is X[3],
alias TP[XLEN] is X[4],
alias T0[XLEN] is X[5],
alias T1[XLEN] is X[6],
alias T2[XLEN] is X[7],
alias S0[XLEN] is X[8],
alias S1[XLEN] is X[9],
alias A0[XLEN] is X[10],
alias A1[XLEN] is X[11],
alias A2[XLEN] is X[12],
alias A3[XLEN] is X[13],
alias A4[XLEN] is X[14],
alias A5[XLEN] is X[15],
alias A6[XLEN] is X[16],
alias A7[XLEN] is X[17],
alias S2[XLEN] is X[18],
alias S3[XLEN] is X[19],
alias S4[XLEN] is X[20],
alias S5[XLEN] is X[21],
alias S6[XLEN] is X[22],
alias S7[XLEN] is X[23],
alias S8[XLEN] is X[24],
alias S9[XLEN] is X[25],
alias S10[XLEN] is X[26],
alias S11[XLEN] is X[27],
alias T3[XLEN] is X[28],
alias T4[XLEN] is X[29],
alias T5[XLEN] is X[30],
alias T6[XLEN] is X[31]
}
}

309
gen_input/RV32I.core_desc
View File

@@ -1,309 +0,0 @@
import "RISCVBase.core_desc"
InsructionSet RV32I extends RISCVBase{
instructions {
LUI{
encoding: imm[31:12]s | rd[4:0] | b0110111;
args_disass: "{name(rd)}, {imm:#05x}";
if(rd!=0) X[rd] <= imm;
}
AUIPC{
encoding: imm[31:12]s | rd[4:0] | b0010111;
args_disass: "{name(rd)}, {imm:#08x}";
if(rd!=0) X[rd] <= PC's+imm;
}
JAL(no_cont){
encoding: imm[20:20]s | imm[10:1]s | imm[11:11]s | imm[19:12]s | rd[4:0] | b1101111;
args_disass: "{name(rd)}, {imm:#0x}";
if(rd!=0) X[rd] <= PC+4;
PC<=PC's+imm;
}
JALR(no_cont){
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b1100111;
args_disass: "{name(rd)}, {name(rs1)}, {imm:#0x}";
val new_pc[XLEN] <= X[rs1]'s+ imm;
val align[XLEN] <= new_pc & 0x2;
if(align != 0){
raise(0, 0);
} else {
if(rd!=0) X[rd] <= PC+4;
PC<=new_pc & ~0x1;
}
}
BEQ(no_cont,cond){
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b000 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]==X[rs2], PC's+imm, PC+4);
}
BNE(no_cont,cond){
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b001 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]!=X[rs2], PC's+imm, PC+4);
}
BLT(no_cont,cond){
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b100 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]s<X[rs2]s, PC's+imm, PC+4);
}
BGE(no_cont,cond) {
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b101 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]s>=X[rs2]s, PC's+imm, PC+4);
}
BLTU(no_cont,cond) {
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b110 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]<X[rs2],PC's+imm, PC+4);
}
BGEU(no_cont,cond) {
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b111 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]>=X[rs2], PC's+imm, PC+4);
}
LB {
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=sext(MEM[offs]);
}
LH {
encoding: imm[11:0]s | rs1[4:0] | b001 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=sext(MEM[offs]{16});
}
LW {
encoding: imm[11:0]s | rs1[4:0] | b010 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=sext(MEM[offs]{32});
}
LBU {
encoding: imm[11:0]s | rs1[4:0] | b100 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=zext(MEM[offs]);
}
LHU {
encoding: imm[11:0]s | rs1[4:0] | b101 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=zext(MEM[offs]{16});
}
SB {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b000 | imm[4:0]s | b0100011;
args_disass:"{name(rs2)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs] <= X[rs2];
}
SH {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b001 | imm[4:0]s | b0100011;
args_disass:"{name(rs2)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{16} <= X[rs2];
}
SW {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b010 | imm[4:0]s | b0100011;
args_disass:"{name(rs2)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{32} <= X[rs2];
}
ADDI {
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0) X[rd] <= X[rs1]'s + imm;
}
SLTI {
encoding: imm[11:0]s | rs1[4:0] | b010 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if (rd != 0) X[rd] <= choose(X[rs1]s < imm's, 1, 0);
}
SLTIU {
encoding: imm[11:0]s | rs1[4:0] | b011 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
val full_imm[XLEN] <= imm's;
if (rd != 0) X[rd] <= choose(X[rs1]'u < full_imm'u, 1, 0);
}
XORI {
encoding: imm[11:0]s | rs1[4:0] | b100 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0) X[rd] <= X[rs1]s ^ imm;
}
ORI {
encoding: imm[11:0]s | rs1[4:0] | b110 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0) X[rd] <= X[rs1]s | imm;
}
ANDI {
encoding: imm[11:0]s | rs1[4:0] | b111 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0) X[rd] <= X[rs1]s & imm;
}
SLLI {
encoding: b0000000 | shamt[4:0] | rs1[4:0] | b001 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(shamt > 31){
raise(0,0);
} else {
if(rd != 0) X[rd] <= shll(X[rs1], shamt);
}
}
SRLI {
encoding: b0000000 | shamt[4:0] | rs1[4:0] | b101 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(shamt > 31){
raise(0,0);
} else {
if(rd != 0) X[rd] <= shrl(X[rs1], shamt);
}
}
SRAI {
encoding: b0100000 | shamt[4:0] | rs1[4:0] | b101 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(shamt > 31){
raise(0,0);
} else {
if(rd != 0) X[rd] <= shra(X[rs1], shamt);
}
}
ADD {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] + X[rs2];
}
SUB {
encoding: b0100000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] - X[rs2];
}
SLL {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= shll(X[rs1], X[rs2]&(XLEN-1));
}
SLT {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if (rd != 0) X[rd] <= choose(X[rs1]s < X[rs2]s, 1, 0);
}
SLTU {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if (rd != 0) X[rd] <= choose(zext(X[rs1]) < zext(X[rs2]), 1, 0);
}
XOR {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b100 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] ^ X[rs2];
}
SRL {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= shrl(X[rs1], X[rs2]&(XLEN-1));
}
SRA {
encoding: b0100000 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= shra(X[rs1], X[rs2]&(XLEN-1));
}
OR {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b110 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] | X[rs2];
}
AND {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b111 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] & X[rs2];
}
FENCE {
encoding: b0000 | pred[3:0] | succ[3:0] | rs1[4:0] | b000 | rd[4:0] | b0001111;
FENCE[fence] <= pred<<4 | succ;
}
FENCE_I(flush) {
encoding: imm[11:0] | rs1[4:0] | b001 | rd[4:0] | b0001111 ;
FENCE[fencei] <= imm;
}
ECALL(no_cont) {
encoding: b000000000000 | b00000 | b000 | b00000 | b1110011;
raise(0, 11);
}
EBREAK(no_cont) {
encoding: b000000000001 | b00000 | b000 | b00000 | b1110011;
raise(0, 3);
}
URET(no_cont) {
encoding: b0000000 | b00010 | b00000 | b000 | b00000 | b1110011;
leave(0);
}
SRET(no_cont) {
encoding: b0001000 | b00010 | b00000 | b000 | b00000 | b1110011;
leave(1);
}
MRET(no_cont) {
encoding: b0011000 | b00010 | b00000 | b000 | b00000 | b1110011;
leave(3);
}
WFI {
encoding: b0001000 | b00101 | b00000 | b000 | b00000 | b1110011;
wait(1);
}
SFENCE.VMA {
encoding: b0001001 | rs2[4:0] | rs1[4:0] | b000 | b00000 | b1110011;
FENCE[fencevmal] <= rs1;
FENCE[fencevmau] <= rs2;
}
CSRRW {
encoding: csr[11:0] | rs1[4:0] | b001 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {name(rs1)}";
val rs_val[XLEN] <= X[rs1];
if(rd!=0){
val csr_val[XLEN] <= CSR[csr];
CSR[csr] <= rs_val;
// make sure Xrd is updated once CSR write succeeds
X[rd] <= csr_val;
} else {
CSR[csr] <= rs_val;
}
}
CSRRS {
encoding: csr[11:0] | rs1[4:0] | b010 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {name(rs1)}";
val xrd[XLEN] <= CSR[csr];
val xrs1[XLEN] <= X[rs1];
if(rd!=0) X[rd] <= xrd;
if(rs1!=0) CSR[csr] <= xrd | xrs1;
}
CSRRC {
encoding: csr[11:0] | rs1[4:0] | b011 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {name(rs1)}";
val xrd[XLEN] <= CSR[csr];
val xrs1[XLEN] <= X[rs1];
if(rd!=0) X[rd] <= xrd;
if(rs1!=0) CSR[csr] <= xrd & ~xrs1;
}
CSRRWI {
encoding: csr[11:0] | zimm[4:0] | b101 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {zimm:#0x}";
if(rd!=0) X[rd] <= CSR[csr];
CSR[csr] <= zext(zimm);
}
CSRRSI {
encoding: csr[11:0] | zimm[4:0] | b110 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {zimm:#0x}";
val res[XLEN] <= CSR[csr];
if(zimm!=0) CSR[csr] <= res | zext(zimm);
// make sure rd is written after csr write succeeds
if(rd!=0) X[rd] <= res;
}
CSRRCI {
encoding: csr[11:0] | zimm[4:0] | b111 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {zimm:#0x}";
val res[XLEN] <= CSR[csr];
if(rd!=0) X[rd] <= res;
if(zimm!=0) CSR[csr] <= res & ~zext(zimm, XLEN);
}
}
}

116
gen_input/RV64I.core_desc
View File

@@ -1,116 +0,0 @@
import "RV32I.core_desc"
InsructionSet RV64I extends RV32I {
instructions{
LWU { // 80000104: 0000ef03 lwu t5,0(ra)
encoding: imm[11:0]s | rs1[4:0] | b110 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=zext(MEM[offs]{32});
}
LD{
encoding: imm[11:0]s | rs1[4:0] | b011 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
if(rd!=0) X[rd]<=sext(MEM[offs]{64});
}
SD{
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b011 | imm[4:0]s | b0100011;
args_disass:"{name(rs2)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{64} <= X[rs2];
}
SLLI {
encoding: b000000 | shamt[5:0] | rs1[4:0] | b001 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0) X[rd] <= shll(X[rs1], shamt);
}
SRLI {
encoding: b000000 | shamt[5:0] | rs1[4:0] | b101 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0) X[rd] <= shrl(X[rs1], shamt);
}
SRAI {
encoding: b010000 | shamt[5:0] | rs1[4:0] | b101 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0) X[rd] <= shra(X[rs1], shamt);
}
ADDIW {
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b0011011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0){
val res[32] <= X[rs1]{32}'s + imm;
X[rd] <= sext(res);
}
}
SLLIW {
encoding: b0000000 | shamt[4:0] | rs1[4:0] | b001 | rd[4:0] | b0011011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0){
val sh_val[32] <= shll(X[rs1]{32}, shamt);
X[rd] <= sext(sh_val);
}
}
SRLIW {
encoding: b0000000 | shamt[4:0] | rs1[4:0] | b101 | rd[4:0] | b0011011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0){
val sh_val[32] <= shrl(X[rs1]{32}, shamt);
X[rd] <= sext(sh_val);
}
}
SRAIW {
encoding: b0100000 | shamt[4:0] | rs1[4:0] | b101 | rd[4:0] | b0011011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0){
val sh_val[32] <= shra(X[rs1]{32}, shamt);
X[rd] <= sext(sh_val);
}
}
ADDW {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0111011;
if(rd != 0){
val res[32] <= X[rs1]{32} + X[rs2]{32};
X[rd] <= sext(res);
}
}
SUBW {
encoding: b0100000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0111011;
if(rd != 0){
val res[32] <= X[rs1]{32} - X[rs2]{32};
X[rd] <= sext(res);
}
}
SLLW {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val mask[32] <= 0x1f;
val count[32] <= X[rs2]{32} & mask;
val sh_val[32] <= shll(X[rs1]{32}, count);
X[rd] <= sext(sh_val);
}
}
SRLW {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val mask[32] <= 0x1f;
val count[32] <= X[rs2]{32} & mask;
val sh_val[32] <= shrl(X[rs1]{32}, count);
X[rd] <= sext(sh_val);
}
}
SRAW {
encoding: b0100000 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val mask[32] <= 0x1f;
val count[32] <= X[rs2]{32} & mask;
val sh_val[32] <= shra(X[rs1]{32}, count);
X[rd] <= sext(sh_val);
}
}
}
}

210
gen_input/RVA.core_desc
View File

@@ -1,210 +0,0 @@
import "RISCVBase.core_desc"
InsructionSet RV32A extends RISCVBase{
instructions{
LR.W {
encoding: b00010 | aq[0:0] | rl[0:0] | b00000 | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}";
if(rd!=0){
val offs[XLEN] <= X[rs1];
X[rd]<= sext(MEM[offs]{32}, XLEN);
RES[offs]{32}<=sext(-1, 32);
}
}
SC.W {
encoding: b00011 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)}";
val offs[XLEN] <= X[rs1];
val res1[32] <= RES[offs]{32};
if(res1!=0)
MEM[offs]{32} <= X[rs2];
if(rd!=0) X[rd]<= choose(res1!=zext(0, 32), 0, 1);
}
AMOSWAP.W{
encoding: b00001 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
if(rd!=0) X[rd]<=sext(MEM[offs]{32});
MEM[offs]{32}<=X[rs2];
}
AMOADD.W{
encoding: b00000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<=res1 + X[rs2];
MEM[offs]{32}<=res2;
}
AMOXOR.W{
encoding: b00100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<=res1 ^ X[rs2];
MEM[offs]{32}<=res2;
}
AMOAND.W{
encoding: b01100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN] <=res1 & X[rs2];
MEM[offs]{32}<=res2;
}
AMOOR.W {
encoding: b01000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<=res1 | X[rs2];
MEM[offs]{32}<=res2;
}
AMOMIN.W{
encoding: b10000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd] <= res1;
val res2[XLEN] <= choose(res1's > X[rs2]s, X[rs2], res1);
MEM[offs]{32} <= res2;
}
AMOMAX.W{
encoding: b10100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<= choose(res1's<X[rs2]s, X[rs2], res1);
MEM[offs]{32}<=res2;
}
AMOMINU.W{
encoding: b11000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<= choose(res1>X[rs2], X[rs2], res1);
MEM[offs]{32}<=res2;
}
AMOMAXU.W{
encoding: b11100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd] <= res1;
val res2[XLEN] <= choose(res1 < X[rs2], X[rs2], res1);
MEM[offs]{32} <= res2;
}
}
}
InsructionSet RV64A extends RV32A {
instructions{
LR.D {
encoding: b00010 | aq[0:0] | rl[0:0] | b00000 | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}";
if(rd!=0){
val offs[XLEN] <= X[rs1];
X[rd]<= sext(MEM[offs]{64}, XLEN);
RES[offs]{64}<=sext(-1, 64);
}
}
SC.D {
encoding: b00011 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)}";
val offs[XLEN] <= X[rs1];
val res[64] <= RES[offs];
if(res!=0){
MEM[offs]{64} <= X[rs2];
if(rd!=0) X[rd]<=0;
} else{
if(rd!=0) X[rd]<= 1;
}
}
AMOSWAP.D{
encoding: b00001 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
if(rd!=0) X[rd] <= sext(MEM[offs]{64});
MEM[offs]{64} <= X[rs2];
}
AMOADD.D{
encoding: b00000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd]<=res;
val res2[XLEN] <= res + X[rs2];
MEM[offs]{64}<=res2;
}
AMOXOR.D{
encoding: b00100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= res ^ X[rs2];
MEM[offs]{64} <= res2;
}
AMOAND.D{
encoding: b01100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= res & X[rs2];
MEM[offs]{64} <= res2;
}
AMOOR.D {
encoding: b01000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= res | X[rs2];
MEM[offs]{64} <= res2;
}
AMOMIN.D{
encoding: b10000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res1[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res1;
val res2[XLEN] <= choose(res1's > X[rs2]s, X[rs2], res1);
MEM[offs]{64} <= res2;
}
AMOMAX.D{
encoding: b10100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= choose(res s < X[rs2]s, X[rs2], res);
MEM[offs]{64} <= res2;
}
AMOMINU.D{
encoding: b11000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= choose(res > X[rs2], X[rs2], res);
MEM[offs]{64} <= res2;
}
AMOMAXU.D{
encoding: b11100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res1[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res1;
val res2[XLEN] <= choose(res1 < X[rs2], X[rs2], res1);
MEM[offs]{64} <= res2;
}
}
}

367
gen_input/RVC.core_desc
View File

@@ -1,367 +0,0 @@
import "RISCVBase.core_desc"
InsructionSet RV32IC extends RISCVBase{
instructions{
JALR(no_cont){ // overwriting the implementation if rv32i, alignment does not need to be word
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b1100111;
args_disass: "{name(rd)}, {name(rs1)}, {imm:#0x}";
val new_pc[XLEN] <= X[rs1]s + imm;
if(rd!=0) X[rd] <= PC+4;
PC<=new_pc & ~0x1;
}
C.ADDI4SPN { //(RES, imm=0)
encoding: b000 | imm[5:4] | imm[9:6] | imm[2:2] | imm[3:3] | rd[2:0] | b00;
args_disass: "{name(rd)}, {imm:#05x}";
if(imm == 0) raise(0, 2);
X[rd+8] <= X[2] + imm;
}
C.LW { // (RV32)
encoding: b010 | uimm[5:3] | rs1[2:0] | uimm[2:2] | uimm[6:6] | rd[2:0] | b00;
args_disass: "{name(8+rd)}, {uimm:#05x}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
X[rd+8] <= sext(MEM[offs]{32});
}
C.SW {//(RV32)
encoding: b110 | uimm[5:3] | rs1[2:0] | uimm[2:2] | uimm[6:6] | rs2[2:0] | b00;
args_disass: "{name(8+rs2)}, {uimm:#05x}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
MEM[offs]{32} <= X[rs2+8];
}
C.ADDI {//(RV32)
encoding:b000 | imm[5:5]s | rs1[4:0] | imm[4:0]s | b01;
args_disass: "{name(rs1)}, {imm:#05x}";
X[rs1] <= X[rs1]'s + imm;
}
C.NOP {
encoding:b000 | b0 | b00000 | b00000 | b01;
}
// C.JAL will be overwritten by C.ADDIW for RV64/128
C.JAL(no_cont) {//(RV32)
encoding: b001 | imm[11:11]s | imm[4:4]s | imm[9:8]s | imm[10:10]s | imm[6:6]s | imm[7:7]s | imm[3:1]s | imm[5:5]s | b01;
args_disass: "{imm:#05x}";
X[1] <= PC+2;
PC<=PC's+imm;
}
C.LI {//(RV32)
encoding:b010 | imm[5:5]s | rd[4:0] | imm[4:0]s | b01;
args_disass: "{name(rd)}, {imm:#05x}";
if(rd == 0) raise(0, 2); //TODO: should it be handled as trap?
X[rd] <= imm;
}
// order matters here as C.ADDI16SP overwrites C.LUI vor rd==2
C.LUI {//(RV32)
encoding:b011 | imm[17:17] | rd[4:0] | imm[16:12]s | b01;
args_disass: "{name(rd)}, {imm:#05x}";
if(rd == 0) raise(0, 2); //TODO: should it be handled as trap?
if(imm == 0) raise(0, 2); //TODO: should it be handled as trap?
X[rd] <= imm;
}
C.ADDI16SP {//(RV32)
encoding:b011 | imm[9:9]s | b00010 | imm[4:4]s | imm[6:6]s | imm[8:7]s | imm[5:5]s | b01;
args_disass: "{imm:#05x}";
X[2] <= X[2]s + imm;
}
C.SRLI {//(RV32 nse)
encoding:b100 | b0 | b00 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shrl(X[rs1_idx], shamt);
}
C.SRAI {//(RV32)
encoding:b100 | b0 | b01 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shra(X[rs1_idx], shamt);
}
C.ANDI {//(RV32)
encoding:b100 | imm[5:5]s | b10 | rs1[2:0] | imm[4:0]s | b01;
args_disass: "{name(8+rs1)}, {imm:#05x}";
val rs1_idx[5] <= rs1 + 8;
X[rs1_idx] <= X[rs1_idx]s & imm;
}
C.SUB {//(RV32)
encoding:b100 | b0 | b11 | rd[2:0] | b00 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rs2)}";
val rd_idx[5] <= rd + 8;
X[rd_idx] <= X[rd_idx] - X[rs2 + 8];
}
C.XOR {//(RV32)
encoding:b100 | b0 | b11 | rd[2:0] | b01 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rs2)}";
val rd_idx[5] <= rd + 8;
X[rd_idx] <= X[rd_idx] ^ X[rs2 + 8];
}
C.OR {//(RV32)
encoding:b100 | b0 | b11 | rd[2:0] | b10 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rs2)}";
val rd_idx[5] <= rd + 8;
X[rd_idx] <= X[rd_idx] | X[rs2 + 8];
}
C.AND {//(RV32)
encoding:b100 | b0 | b11 | rd[2:0] | b11 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rs2)}";
val rd_idx[5] <= rd + 8;
X[rd_idx] <= X[rd_idx] & X[rs2 + 8];
}
C.J(no_cont) {//(RV32)
encoding:b101 | imm[11:11]s | imm[4:4]s | imm[9:8]s | imm[10:10]s | imm[6:6]s | imm[7:7]s | imm[3:1]s | imm[5:5]s | b01;
args_disass: "{imm:#05x}";
PC<=PC's+imm;
}
C.BEQZ(no_cont,cond) {//(RV32)
encoding:b110 | imm[8:8]s | imm[4:3]s | rs1[2:0] | imm[7:6]s |imm[2:1]s | imm[5:5]s | b01;
args_disass: "{name(8+rs1)}, {imm:#05x}";
PC<=choose(X[rs1+8]==0, PC's+imm, PC+2);
}
C.BNEZ(no_cont,cond) {//(RV32)
encoding:b111 | imm[8:8]s | imm[4:3]s | rs1[2:0] | imm[7:6]s | imm[2:1]s | imm[5:5]s | b01;
args_disass: "{name(8+rs1)}, {imm:#05x}";
PC<=choose(X[rs1+8]!=0, PC's+imm, PC+2);
}
C.SLLI {//(RV32)
encoding:b000 | b0 | rs1[4:0] | shamt[4:0] | b10;
args_disass: "{name(rs1)}, {shamt}";
if(rs1 == 0) raise(0, 2);
X[rs1] <= shll(X[rs1], shamt);
}
C.LWSP {//
encoding:b010 | uimm[5:5] | rd[4:0] | uimm[4:2] | uimm[7:6] | b10;
args_disass: "{name(rd)}, sp, {uimm:#05x}";
val offs[XLEN] <= X[2] + uimm;
X[rd] <= sext(MEM[offs]{32});
}
// order matters as C.JR is a special case of C.MV
C.MV {//(RV32)
encoding:b100 | b0 | rd[4:0] | rs2[4:0] | b10;
args_disass: "{name(rd)}, {name(rs2)}";
X[rd] <= X[rs2];
}
C.JR(no_cont) {//(RV32)
encoding:b100 | b0 | rs1[4:0] | b00000 | b10;
args_disass: "{name(rs1)}";
PC <= X[rs1];
}
// order matters as C.EBREAK is a special case of C.JALR which is a special case of C.ADD
C.ADD {//(RV32)
encoding:b100 | b1 | rd[4:0] | rs2[4:0] | b10;
args_disass: "{name(rd)}, {name(rs2)}";
X[rd] <= X[rd] + X[rs2];
}
C.JALR(no_cont) {//(RV32)
encoding:b100 | b1 | rs1[4:0] | b00000 | b10;
args_disass: "{name(rs1)}";
X[1] <= PC+2;
PC<=X[rs1];
}
C.EBREAK(no_cont) {//(RV32)
encoding:b100 | b1 | b00000 | b00000 | b10;
raise(0, 3);
}
C.SWSP {//
encoding:b110 | uimm[5:2] | uimm[7:6] | rs2[4:0] | b10;
args_disass: "{name(rs2)}, {uimm:#05x}(sp)";
val offs[XLEN] <= X[2] + uimm;
MEM[offs]{32} <= X[rs2];
}
DII(no_cont) { // Defined Illegal Instruction
encoding:b000 | b0 | b00000 | b00000 | b00;
raise(0, 2);
}
}
}
InsructionSet RV32FC extends RV32IC{
constants {
FLEN
}
registers {
[31:0] F[FLEN]
}
instructions{
C.FLW {
encoding: b011 | uimm[5:3] | rs1[2:0] | uimm[2:2] | uimm[6:6] | rd[2:0] | b00;
args_disass:"f(8+{rd}), {uimm}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
val res[32] <= MEM[offs]{32};
if(FLEN==32)
F[rd+8] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd+8] <= (upper<<32) | zext(res, FLEN);
}
}
C.FSW {
encoding: b111 | uimm[5:3] | rs1[2:0] | uimm[2:2] | uimm[6:6] | rs2[2:0] | b00;
args_disass:"f(8+{rs2}), {uimm}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
MEM[offs]{32}<=F[rs2+8]{32};
}
C.FLWSP {
encoding:b011 | uimm[5:5] | rd[4:0] | uimm[4:2] | uimm[7:6] | b10;
args_disass:"f{rd}, {uimm}(x2)";
val offs[XLEN] <= X[2]+uimm;
val res[32] <= MEM[offs]{32};
if(FLEN==32)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
C.FSWSP {
encoding:b111 | uimm[5:2] | uimm[7:6] | rs2[4:0] | b10;
args_disass:"f{rs2}, {uimm}(x2), ";
val offs[XLEN] <= X[2]+uimm;
MEM[offs]{32}<=F[rs2]{32};
}
}
}
InsructionSet RV32DC extends RV32IC{
constants {
FLEN
}
registers {
[31:0] F[FLEN]
}
instructions{
C.FLD { //(RV32/64)
encoding: b001 | uimm[5:3] | rs1[2:0] | uimm[7:6] | rd[2:0] | b00;
args_disass:"f(8+{rd}), {uimm}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
val res[64] <= MEM[offs]{64};
if(FLEN==64)
F[rd+8] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd+8] <= (upper<<64) | res;
}
}
C.FSD { //(RV32/64)
encoding: b101 | uimm[5:3] | rs1[2:0] | uimm[7:6] | rs2[2:0] | b00;
args_disass:"f(8+{rs2}), {uimm}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
MEM[offs]{64}<=F[rs2+8]{64};
}
C.FLDSP {//(RV32/64)
encoding:b001 | uimm[5:5] | rd[4:0] | uimm[4:3] | uimm[8:6] | b10;
args_disass:"f{rd}, {uimm}(x2)";
val offs[XLEN] <= X[2]+uimm;
val res[64] <= MEM[offs]{64};
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | zext(res, FLEN);
}
}
C.FSDSP {//(RV32/64)
encoding:b101 | uimm[5:3] | uimm[8:6] | rs2[4:0] | b10;
args_disass:"f{rs2}, {uimm}(x2), ";
val offs[XLEN] <= X[2]+uimm;
MEM[offs]{64}<=F[rs2]{64};
}
}
}
InsructionSet RV64IC extends RV32IC {
instructions{
C.LD {//(RV64/128)
encoding:b011 | uimm[5:3] | rs1[2:0] | uimm[7:6] | rd[2:0] | b00;
args_disass: "{name(8+rd)}, {uimm},({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8] + uimm;
X[rd+8]<=sext(MEM[offs]{64});
}
C.SD { //(RV64/128)
encoding:b111 | uimm[5:3] | rs1[2:0] | uimm[7:6] | rs2[2:0] | b00;
args_disass: "{name(8+rs2)}, {uimm},({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8] + uimm;
MEM[offs]{64} <= X[rs2+8];
}
C.SUBW {//(RV64/128, RV32 res)
encoding:b100 | b1 | b11 | rd[2:0] | b00 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rd)}, {name(8+rs2)}";
val res[32] <= X[rd+8]{32} - X[rs2+8]{32};
X[rd+8] <= sext(res);
}
C.ADDW {//(RV64/128 RV32 res)
encoding:b100 | b1 | b11 | rd[2:0] | b01 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rd)}, {name(8+rs2)}";
val res[32] <= X[rd+8]{32} + X[rs2+8]{32};
X[rd+8] <= sext(res);
}
C.ADDIW {//(RV64/128)
encoding:b001 | imm[5:5]s | rs1[4:0] | imm[4:0]s | b01;
args_disass: "{name(rs1)}, {imm:#05x}";
if(rs1 != 0){
val res[32] <= X[rs1]{32}'s + imm;
X[rs1] <= sext(res);
}
}
C.SRLI {//(RV64)
encoding:b100 | shamt[5:5] | b00 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shrl(X[rs1_idx], shamt);
}
C.SRAI {//(RV64)
encoding:b100 | shamt[5:5] | b01 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shra(X[rs1_idx], shamt);
}
C.SLLI {//(RV64)
encoding:b000 | shamt[5:5] | rs1[4:0] | shamt[4:0] | b10;
args_disass: "{name(rs1)}, {shamt}";
if(rs1 == 0) raise(0, 2);
X[rs1] <= shll(X[rs1], shamt);
}
C.LDSP {//(RV64/128
encoding:b011 | uimm[5:5] | rd[4:0] | uimm[4:3] | uimm[8:6] | b10;
args_disass:"{name(rd)}, {uimm}(sp)";
val offs[XLEN] <= X[2] + uimm;
if(rd!=0) X[rd]<=sext(MEM[offs]{64});
}
C.SDSP {//(RV64/128)
encoding:b111 | uimm[5:3] | uimm[8:6] | rs2[4:0] | b10;
args_disass:"{name(rs2)}, {uimm}(sp)";
val offs[XLEN] <= X[2] + uimm;
MEM[offs]{64} <= X[rs2];
}
}
}
InsructionSet RV128IC extends RV64IC {
instructions{
C.SRLI {//(RV128)
encoding:b100 | shamt[5:5] | b00 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shrl(X[rs1_idx], shamt);
}
C.SRAI {//(RV128)
encoding:b100 | shamt[5:5] | b01 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shra(X[rs1_idx], shamt);
}
C.SLLI {//(RV128)
encoding:b000 | shamt[5:5] | rs1[4:0] | shamt[4:0] | b10;
args_disass: "{name(rs1)}, {shamt}";
if(rs1 == 0) raise(0, 2);
X[rs1] <= shll(X[rs1], shamt);
}
C.LQ { //(RV128)
encoding:b001 | uimm[5:4] | uimm[8:8] | rs1[2:0] | uimm[7:6] | rd[2:0] | b00;
}
C.SQ { //(RV128)
encoding:b101 | uimm[5:4] | uimm[8:8] | rs1[2:0] | uimm[7:6] | rs2[2:0] | b00;
}
C.SQSP {//(RV128)
encoding:b101 | uimm[5:4] | uimm[9:6] | rs2[4:0] | b10;
}
}
}

360
gen_input/RVD.core_desc
View File

@@ -1,360 +0,0 @@
import "RISCVBase.core_desc"
InsructionSet RV32D extends RISCVBase{
constants {
FLEN, FFLAG_MASK := 0x1f
}
registers {
[31:0] F[FLEN], FCSR[32]
}
instructions{
FLD {
encoding: imm[11:0]s | rs1[4:0] | b011 | rd[4:0] | b0000111;
args_disass:"f{rd}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
val res[64] <= MEM[offs]{64};
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FSD {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b011 | imm[4:0]s | b0100111;
args_disass:"f{rs2}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{64}<=F[rs2]{64};
}
FMADD.D {
encoding: rs3[4:0] | b01 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1000011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<= F[rs1]f * F[rs2]f + F[rs3]f;
val res[64] <= fdispatch_fmadd_d(F[rs1]{64}, F[rs2]{64}, F[rs3]{64}, zext(0, 64), choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMSUB.D {
encoding: rs3[4:0] | b01 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1000111;
args_disass:"{name(rd)}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=F[rs1]f * F[rs2]f - F[rs3]f;
val res[64] <= fdispatch_fmadd_d(F[rs1]{64}, F[rs2]{64}, F[rs3]{64}, zext(1, 32), choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FNMADD.D {
encoding: rs3[4:0] | b01 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1001111;
args_disass:"{name(rd)}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=-F[rs1]f * F[rs2]f + F[rs3]f;
val res[64] <= fdispatch_fmadd_d(F[rs1]{64}, F[rs2]{64}, F[rs3]{64}, zext(2, 32), choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FNMSUB.D {
encoding: rs3[4:0] | b01 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1001011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=-F[rs1]f * F[rs2]f - F[rs3]f;
val res[64] <= fdispatch_fmadd_d(F[rs1]{64}, F[rs2]{64}, F[rs3]{64}, zext(3, 32), choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FADD.D {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f + F[rs2]f;
val res[64] <= fdispatch_fadd_d(F[rs1]{64}, F[rs2]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSUB.D {
encoding: b0000101 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f - F[rs2]f;
val res[64] <= fdispatch_fsub_d(F[rs1]{64}, F[rs2]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMUL.D {
encoding: b0001001 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f * F[rs2]f;
val res[64] <= fdispatch_fmul_d(F[rs1]{64}, F[rs2]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FDIV.D {
encoding: b0001101 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f / F[rs2]f;
val res[64] <= fdispatch_fdiv_d(F[rs1]{64}, F[rs2]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSQRT.D {
encoding: b0101101 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
//F[rd]f<=sqrt(F[rs1]f);
val res[64] <= fdispatch_fsqrt_d(F[rs1]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSGNJ.D {
encoding: b0010001 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
val ONE[64] <= 1;
val MSK1[64] <= ONE<<63;
val MSK2[64] <= MSK1-1;
val res[64] <= (F[rs1]{64} & MSK2) | (F[rs2]{64} & MSK1);
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FSGNJN.D {
encoding: b0010001 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
val ONE[64] <= 1;
val MSK1[64] <= ONE<<63;
val MSK2[64] <= MSK1-1;
val res[64] <= (F[rs1]{64} & MSK2) | (~F[rs2]{64} & MSK1);
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FSGNJX.D {
encoding: b0010001 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
val ONE[64] <= 1;
val MSK1[64] <= ONE<<63;
val res[64] <= F[rs1]{64} ^ (F[rs2]{64} & MSK1);
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FMIN.D {
encoding: b0010101 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
//F[rd]f<= choose(F[rs1]f<F[rs2]f, F[rs1]f, F[rs2]f);
val res[64] <= fdispatch_fsel_d(F[rs1]{64}, F[rs2]{64}, zext(0, 32));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMAX.D {
encoding: b0010101 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
//F[rd]f<= choose(F[rs1]f>F[rs2]f, F[rs1]f, F[rs2]f);
val res[64] <= fdispatch_fsel_d(F[rs1]{64}, F[rs2]{64}, zext(1, 32));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.S.D {
encoding: b0100000 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}";
val res[32] <= fdispatch_fconv_d2f(F[rs1], rm{8});
// NaN boxing
val upper[FLEN] <= -1;
F[rd] <= upper<<32 | zext(res, FLEN);
}
FCVT.D.S {
encoding: b0100001 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}";
val res[64] <= fdispatch_fconv_f2d(F[rs1]{32}, rm{8});
if(FLEN==64){
F[rd] <= res;
} else {
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FEQ.D {
encoding: b1010001 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
X[rd]<=zext(fdispatch_fcmp_d(F[rs1]{64}, F[rs2]{64}, zext(0, 32)));
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FLT.D {
encoding: b1010001 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
X[rd]<=zext(fdispatch_fcmp_d(F[rs1]{64}, F[rs2]{64}, zext(2, 32)));
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FLE.D {
encoding: b1010001 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
X[rd]<=zext(fdispatch_fcmp_d(F[rs1]{64}, F[rs2]{64}, zext(1, 32)));
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCLASS.D {
encoding: b1110001 | b00000 | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<=fdispatch_fclass_d(F[rs1]{64});
}
FCVT.W.D {
encoding: b1100001 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<= sext(fdispatch_fcvt_64_32(F[rs1]{64}, zext(0, 32), rm{8}), XLEN);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.WU.D {
encoding: b1100001 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
//FIXME: should be zext accodring to spec but needs to be sext according to tests
X[rd]<= sext(fdispatch_fcvt_64_32(F[rs1]{64}, zext(1, 32), rm{8}), XLEN);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.D.W {
encoding: b1101001 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
val res[64] <= fdispatch_fcvt_32_64(sext(X[rs1]{32},64), zext(2, 32), rm{8});
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FCVT.D.WU {
encoding: b1101001 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
val res[64] <=fdispatch_fcvt_32_64(zext(X[rs1]{32},64), zext(3,32), rm{8});
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
}
}
InsructionSet RV64D extends RV32D{
instructions{
FCVT.L.D {
encoding: b1100001 | b00010 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<= sext(fdispatch_fcvt_d(F[rs1]{64}, zext(0, 32), rm{8}), XLEN);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.LU.D {
encoding: b1100001 | b00011 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<= sext(fdispatch_fcvt_d(F[rs1]{64}, zext(1, 32), rm{8}), XLEN);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.D.L {
encoding: b1101001 | b00010 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
val res[64] <= fdispatch_fcvt_d(sext(X[rs1],64), zext(2, 32), rm{8});
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FCVT.D.LU {
encoding: b1101001 | b00011 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
val res[64] <=fdispatch_fcvt_d(zext(X[rs1],64), zext(3,32), rm{8});
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FMV.X.D {
encoding: b1110001 | b00000 | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<=sext(F[rs1]);
}
FMV.D.X {
encoding: b1111001 | b00000 | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
F[rd] <= zext(X[rs1]);
}
}
}

400
gen_input/RVF.core_desc
View File

@@ -1,400 +0,0 @@
import "RV32I.core_desc"
InsructionSet RV32F extends RV32I{
constants {
FLEN, FFLAG_MASK := 0x1f
}
registers {
[31:0] F[FLEN], FCSR[32]
}
instructions{
FLW {
encoding: imm[11:0]s | rs1[4:0] | b010 | rd[4:0] | b0000111;
args_disass:"f{rd}, {imm}(x{rs1})";
val offs[XLEN] <= X[rs1]'s + imm;
val res[32] <= MEM[offs]{32};
if(FLEN==32)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FSW {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b010 | imm[4:0]s | b0100111;
args_disass:"f{rs2}, {imm}(x{rs1})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{32}<=F[rs2]{32};
}
FMADD.S {
encoding: rs3[4:0] | b00 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1000011;
args_disass:"x{rd}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<= F[rs1]f * F[rs2]f + F[rs3]f;
if(FLEN==32)
F[rd] <= fdispatch_fmadd_s(F[rs1], F[rs2], F[rs3], zext(0, 32), choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val frs3[32] <= fdispatch_unbox_s(F[rs3]);
val res[32] <= fdispatch_fmadd_s(frs1, frs2, frs3, zext(0, 32), choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMSUB.S {
encoding: rs3[4:0] | b00 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1000111;
args_disass:"x{rd}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=F[rs1]f * F[rs2]f - F[rs3]f;
if(FLEN==32)
F[rd] <= fdispatch_fmadd_s(F[rs1], F[rs2], F[rs3], zext(1, 32), choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val frs3[32] <= fdispatch_unbox_s(F[rs3]);
val res[32] <= fdispatch_fmadd_s(frs1, frs2, frs3, zext(1, 32), choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FNMADD.S {
encoding: rs3[4:0] | b00 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1001111;
args_disass:"x{rd}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=-F[rs1]f * F[rs2]f + F[rs3]f;
if(FLEN==32)
F[rd] <= fdispatch_fmadd_s(F[rs1], F[rs2], F[rs3], zext(2, 32), choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val frs3[32] <= fdispatch_unbox_s(F[rs3]);
val res[32] <= fdispatch_fmadd_s(frs1, frs2, frs3, zext(2, 32), choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FNMSUB.S {
encoding: rs3[4:0] | b00 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1001011;
args_disass:"x{rd}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=-F[rs1]f * F[rs2]f - F[rs3]f;
if(FLEN==32)
F[rd] <= fdispatch_fmadd_s(F[rs1], F[rs2], F[rs3], zext(3, 32), choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val frs3[32] <= fdispatch_unbox_s(F[rs3]);
val res[32] <= fdispatch_fmadd_s(frs1, frs2, frs3, zext(3, 32), choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FADD.S {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f + F[rs2]f;
if(FLEN==32)
F[rd] <= fdispatch_fadd_s(F[rs1], F[rs2], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fadd_s(frs1, frs2, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSUB.S {
encoding: b0000100 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f - F[rs2]f;
if(FLEN==32)
F[rd] <= fdispatch_fsub_s(F[rs1], F[rs2], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fsub_s(frs1, frs2, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMUL.S {
encoding: b0001000 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f * F[rs2]f;
if(FLEN==32)
F[rd] <= fdispatch_fmul_s(F[rs1], F[rs2], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fmul_s(frs1, frs2, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FDIV.S {
encoding: b0001100 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f / F[rs2]f;
if(FLEN==32)
F[rd] <= fdispatch_fdiv_s(F[rs1], F[rs2], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fdiv_s(frs1, frs2, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSQRT.S {
encoding: b0101100 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}";
//F[rd]f<=sqrt(F[rs1]f);
if(FLEN==32)
F[rd] <= fdispatch_fsqrt_s(F[rs1], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val res[32] <= fdispatch_fsqrt_s(frs1, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSGNJ.S {
encoding: b0010000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
if(FLEN==32)
F[rd] <= (F[rs1] & 0x7fffffff) | (F[rs2] & 0x80000000);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= (frs1 & 0x7fffffff) | (frs2 & 0x80000000);
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FSGNJN.S {
encoding: b0010000 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
if(FLEN==32)
F[rd] <= (F[rs1] & 0x7fffffff) | (~F[rs2] & 0x80000000);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= (frs1 & 0x7fffffff) | (~frs2 & 0x80000000);
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FSGNJX.S {
encoding: b0010000 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
if(FLEN==32)
F[rd] <= F[rs1] ^ (F[rs2] & 0x80000000);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= frs1 ^ (frs2 & 0x80000000);
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FMIN.S {
encoding: b0010100 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
//F[rd]f<= choose(F[rs1]f<F[rs2]f, F[rs1]f, F[rs2]f);
if(FLEN==32)
F[rd] <= fdispatch_fsel_s(F[rs1], F[rs2], zext(0, 32));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fsel_s(frs1, frs2, zext(0, 32));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMAX.S {
encoding: b0010100 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
//F[rd]f<= choose(F[rs1]f>F[rs2]f, F[rs1]f, F[rs2]f);
if(FLEN==32)
F[rd] <= fdispatch_fsel_s(F[rs1], F[rs2], zext(1, 32));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fsel_s(frs1, frs2, zext(1, 32));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.W.S {
encoding: b1100000 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
if(FLEN==32)
X[rd] <= sext(fdispatch_fcvt_s(F[rs1], zext(0, 32), rm{8}), XLEN);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
X[rd]<= sext(fdispatch_fcvt_s(frs1, zext(0, 32), rm{8}), XLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.WU.S {
encoding: b1100000 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
//FIXME: according to the spec it should be zero-extended not sign extended
if(FLEN==32)
X[rd]<= sext(fdispatch_fcvt_s(F[rs1], zext(1, 32), rm{8}), XLEN);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
X[rd]<= sext(fdispatch_fcvt_s(frs1, zext(1, 32), rm{8}), XLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FEQ.S {
encoding: b1010000 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
if(FLEN==32)
X[rd]<=zext(fdispatch_fcmp_s(F[rs1], F[rs2], zext(0, 32)));
else {
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
X[rd]<=zext(fdispatch_fcmp_s(frs1, frs2, zext(0, 32)));
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FLT.S {
encoding: b1010000 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
if(FLEN==32)
X[rd]<=zext(fdispatch_fcmp_s(F[rs1], F[rs2], zext(2, 32)));
else {
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
X[rd]<=zext(fdispatch_fcmp_s(frs1, frs2, zext(2, 32)));
}
X[rd]<=fdispatch_fcmp_s(F[rs1]{32}, F[rs2]{32}, zext(2, 32));
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FLE.S {
encoding: b1010000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
if(FLEN==32)
X[rd]<=zext(fdispatch_fcmp_s(F[rs1], F[rs2], zext(1, 32)));
else {
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
X[rd]<=zext(fdispatch_fcmp_s(frs1, frs2, zext(1, 32)));
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCLASS.S {
encoding: b1110000 | b00000 | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<=fdispatch_fclass_s(fdispatch_unbox_s(F[rs1]));
}
FCVT.S.W {
encoding: b1101000 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
if(FLEN==32)
F[rd] <= fdispatch_fcvt_s(X[rs1]{32}, zext(2, 32), rm{8});
else { // NaN boxing
val res[32] <= fdispatch_fcvt_s(X[rs1]{32}, zext(2, 32), rm{8});
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FCVT.S.WU {
encoding: b1101000 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
if(FLEN==32)
F[rd] <=fdispatch_fcvt_s(X[rs1]{32}, zext(3,32), rm{8});
else { // NaN boxing
val res[32] <=fdispatch_fcvt_s(X[rs1]{32}, zext(3,32), rm{8});
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FMV.X.W {
encoding: b1110000 | b00000 | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<=sext(F[rs1]{32});
}
FMV.W.X {
encoding: b1111000 | b00000 | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
if(FLEN==32)
F[rd] <= X[rs1]{32};
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(X[rs1]{32}, FLEN);
}
}
}
}
InsructionSet RV64F extends RV32F{
instructions{
FCVT.L.S { // fp to 64bit signed integer
encoding: b1100000 | b00010 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"x{rd}, f{rs1}";
val res[64] <= fdispatch_fcvt_32_64(fdispatch_unbox_s(F[rs1]), zext(0, 32), rm{8});
X[rd]<= sext(res);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.LU.S { // fp to 64bit unsigned integer
encoding: b1100000 | b00011 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"x{rd}, f{rs1}";
val res[64] <= fdispatch_fcvt_32_64(fdispatch_unbox_s(F[rs1]), zext(1, 32), rm{8});
X[rd]<= zext(res);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.S.L { // 64bit signed int to to fp
encoding: b1101000 | b00010 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, x{rs1}";
val res[32] <= fdispatch_fcvt_64_32(X[rs1], zext(2, 32));
if(FLEN==32)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FCVT.S.LU { // 64bit unsigned int to to fp
encoding: b1101000 | b00011 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, x{rs1}";
val res[32] <=fdispatch_fcvt_64_32(X[rs1], zext(3,32));
if(FLEN==32)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
}
}

160
gen_input/RVM.core_desc
View File

@@ -1,160 +0,0 @@
import "RISCVBase.core_desc"
InsructionSet RV32M extends RISCVBase {
constants {
MAXLEN:=128
}
instructions{
MUL{
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val res[MAXLEN] <= zext(X[rs1], MAXLEN) * zext(X[rs2], MAXLEN);
X[rd]<= zext(res , XLEN);
}
}
MULH {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val res[MAXLEN] <= sext(X[rs1], MAXLEN) * sext(X[rs2], MAXLEN);
X[rd]<= zext(res >> XLEN, XLEN);
}
}
MULHSU {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val res[MAXLEN] <= sext(X[rs1], MAXLEN) * zext(X[rs2], MAXLEN);
X[rd]<= zext(res >> XLEN, XLEN);
}
}
MULHU {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val res[MAXLEN] <= zext(X[rs1], MAXLEN) * zext(X[rs2], MAXLEN);
X[rd]<= zext(res >> XLEN, XLEN);
}
}
DIV {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b100 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0){
val M1[XLEN] <= -1;
val XLM1[8] <= XLEN-1;
val ONE[XLEN] <= 1;
val MMIN[XLEN] <= ONE<<XLM1;
if(X[rs1]==MMIN && X[rs2]==M1)
X[rd] <= MMIN;
else
X[rd] <= X[rs1]s / X[rs2]s;
}else
X[rd] <= -1;
}
}
DIVU {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0)
X[rd] <= X[rs1] / X[rs2];
else
X[rd] <= -1;
}
}
REM {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b110 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0) {
val M1[XLEN] <= -1; // constant -1
val XLM1[32] <= XLEN-1;
val ONE[XLEN] <= 1;
val MMIN[XLEN] <= ONE<<XLM1; // -2^(XLEN-1)
if(X[rs1]==MMIN && X[rs2]==M1)
X[rd] <= 0;
else
X[rd] <= X[rs1]'s % X[rs2]'s;
} else
X[rd] <= X[rs1];
}
}
REMU {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b111 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0)
X[rd] <= X[rs1] % X[rs2];
else
X[rd] <= X[rs1];
}
}
}
}
InsructionSet RV64M extends RV32M {
instructions{
MULW{
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
X[rd]<= sext(X[rs1]{32} * X[rs2]{32});
}
}
DIVW {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b100 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0){
val M1[32] <= -1;
val ONE[32] <= 1;
val MMIN[32] <= ONE<<31;
if(X[rs1]{32}==MMIN && X[rs2]{32}==M1)
X[rd] <= -1<<31;
else
X[rd] <= sext(X[rs1]{32}s / X[rs2]{32}s);
}else
X[rd] <= -1;
}
}
DIVUW {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]{32}!=0)
X[rd] <= sext(X[rs1]{32} / X[rs2]{32});
else
X[rd] <= -1;
}
}
REMW {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b110 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0) {
val M1[32] <= -1; // constant -1
val ONE[32] <= 1;
val MMIN[32] <= ONE<<31; // -2^(XLEN-1)
if(X[rs1]{32}==MMIN && X[rs2]==M1)
X[rd] <= 0;
else
X[rd] <= sext(X[rs1]{32}s % X[rs2]{32}s);
} else
X[rd] <= sext(X[rs1]{32});
}
}
REMUW {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b111 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]{32}!=0)
X[rd] <= sext(X[rs1]{32} % X[rs2]{32});
else
X[rd] <= sext(X[rs1]{32});
}
}
}
}

28
gen_input/TGFS.core_desc Normal file
View File

@@ -0,0 +1,28 @@
import "CoreDSL-Instruction-Set-Description/RV32I.core_desc"
import "CoreDSL-Instruction-Set-Description/RVM.core_desc"
import "CoreDSL-Instruction-Set-Description/RVC.core_desc"
Core TGF_B provides RV32I {
constants {
XLEN:=32;
PCLEN:=32;
// definitions for the architecture wrapper
// XL ZYXWVUTSRQPONMLKJIHGFEDCBA
MISA_VAL:=0b01000000000000000000000100000000;
PGSIZE := 0x1000; //1 << 12;
PGMASK := 0xfff; //PGSIZE-1
}
}
Core TGF_C provides RV32I, RV32M, RV32IC {
constants {
XLEN:=32;
PCLEN:=32;
MUL_LEN:=64;
// definitions for the architecture wrapper
// XL ZYXWVUTSRQPONMLKJIHGFEDCBA
MISA_VAL:=0b01000000000000000001000100000100;
PGSIZE := 0x1000; //1 << 12;
PGMASK := 0xfff; //PGSIZE-1
}
}

10
gen_input/minres_rv.core_desc
View File

@@ -6,6 +6,7 @@ import "RVC.core_desc"
import "RVF.core_desc" import "RVF.core_desc"
import "RVD.core_desc" import "RVD.core_desc"
Core MNRV32 provides RV32I, RV32IC { Core MNRV32 provides RV32I, RV32IC {
constants { constants {
XLEN:=32; XLEN:=32;
@@ -17,11 +18,12 @@ Core MNRV32 provides RV32I, RV32IC {
PGMASK := 0xfff; //PGSIZE-1 PGMASK := 0xfff; //PGSIZE-1
} }
} }
/*
Core RV32IMAC provides RV32I, RV32M, RV32A, RV32IC { Core RV32IMAC provides RV32I, RV32M, RV32A, RV32IC {
constants { constants {
XLEN:=32; XLEN:=32;
PCLEN:=32; PCLEN:=32;
MUL_LEN:=64;
// definitions for the architecture wrapper // definitions for the architecture wrapper
// XL ZYXWVUTSRQPONMLKJIHGFEDCBA // XL ZYXWVUTSRQPONMLKJIHGFEDCBA
MISA_VAL:=0b01000000000101000001000100000101; MISA_VAL:=0b01000000000101000001000100000101;
@@ -35,6 +37,7 @@ Core RV32GC provides RV32I, RV32M, RV32A, RV32F, RV32D, RV32IC, RV32FC, RV32DC {
XLEN:=32; XLEN:=32;
FLEN:=64; FLEN:=64;
PCLEN:=32; PCLEN:=32;
MUL_LEN:=64;
// definitions for the architecture wrapper // definitions for the architecture wrapper
// XL ZYXWVUTSRQPONMLKJIHGFEDCBA // XL ZYXWVUTSRQPONMLKJIHGFEDCBA
MISA_VAL:=0b01000000000101000001000100101101; MISA_VAL:=0b01000000000101000001000100101101;
@@ -55,11 +58,12 @@ Core RV64I provides RV64I {
} }
} }
Core RV64GC provides RV64I, RV64M, RV64A, RV64F, RV64D, RV64IC, RV32FC, RV32DC { Core RV64GC provides RV64I, RV64M, RV64A, RV64F, RV64D, RV32FC, RV32DC, RV64IC {
constants { constants {
XLEN:=64; XLEN:=64;
FLEN:=64; FLEN:=64;
PCLEN:=64; PCLEN:=64;
MUL_LEN:=128;
// definitions for the architecture wrapper // definitions for the architecture wrapper
// XL ZYXWVUTSRQPONMLKJIHGFEDCBA // XL ZYXWVUTSRQPONMLKJIHGFEDCBA
MISA_VAL:=0b01000000000101000001000100101101; MISA_VAL:=0b01000000000101000001000100101101;
@@ -67,4 +71,4 @@ Core RV64GC provides RV64I, RV64M, RV64A, RV64F, RV64D, RV64IC, RV32FC, RV32DC {
PGMASK := 0xfff; //PGSIZE-1 PGMASK := 0xfff; //PGSIZE-1
} }
} }
*/

4
gen_input/templates/interp/incl-CORENAME.h.gtl
View File

@@ -172,6 +172,8 @@ struct ${coreDef.name.toLowerCase()}: public arch_if {
inline bool should_stop() { return interrupt_sim; } inline bool should_stop() { return interrupt_sim; }
inline uint64_t stop_code() { return interrupt_sim; }
inline phys_addr_t v2p(const iss::addr_t& addr){ inline phys_addr_t v2p(const iss::addr_t& addr){
if (addr.space != traits<${coreDef.name.toLowerCase()}>::MEM || addr.type == iss::address_type::PHYSICAL || if (addr.space != traits<${coreDef.name.toLowerCase()}>::MEM || addr.type == iss::address_type::PHYSICAL ||
addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) { addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) {
@@ -204,7 +206,7 @@ protected:
std::array<address_type, 4> addr_mode; std::array<address_type, 4> addr_mode;
bool interrupt_sim=false; uint64_t interrupt_sim=0;
<% <%
def fcsr = allRegs.find {it.name=='FCSR'} def fcsr = allRegs.find {it.name=='FCSR'}
if(fcsr != null) {%> if(fcsr != null) {%>

10
gen_input/templates/interp/src-CORENAME.cpp.gtl
View File

@@ -70,17 +70,7 @@ def getRegisterAliasNames(){
%> %>
#include "util/ities.h" #include "util/ities.h"
#include <util/logging.h> #include <util/logging.h>
#include <elfio/elfio.hpp>
#include <iss/arch/${coreDef.name.toLowerCase()}.h> #include <iss/arch/${coreDef.name.toLowerCase()}.h>
#ifdef __cplusplus
extern "C" {
#endif
#include <ihex.h>
#ifdef __cplusplus
}
#endif
#include <cstdio> #include <cstdio>
#include <cstring> #include <cstring>
#include <fstream> #include <fstream>

3
gen_input/templates/interp/vm-vm_CORENAME.cpp.gtl
View File

@@ -30,8 +30,9 @@
* *
*******************************************************************************/ *******************************************************************************/
#include "../fp_functions.h"
#include <iss/arch/${coreDef.name.toLowerCase()}.h> #include <iss/arch/${coreDef.name.toLowerCase()}.h>
#include <iss/arch/riscv_hart_msu_vp.h> #include <iss/arch/riscv_hart_m_p.h>
#include <iss/debugger/gdb_session.h> #include <iss/debugger/gdb_session.h>
#include <iss/debugger/server.h> #include <iss/debugger/server.h>
#include <iss/iss.h> #include <iss/iss.h>

4
gen_input/templates/llvm/incl-CORENAME.h.gtl
View File

@@ -172,6 +172,8 @@ struct ${coreDef.name.toLowerCase()}: public arch_if {
inline bool should_stop() { return interrupt_sim; } inline bool should_stop() { return interrupt_sim; }
inline uint64_t stop_code() { return interrupt_sim; }
inline phys_addr_t v2p(const iss::addr_t& addr){ inline phys_addr_t v2p(const iss::addr_t& addr){
if (addr.space != traits<${coreDef.name.toLowerCase()}>::MEM || addr.type == iss::address_type::PHYSICAL || if (addr.space != traits<${coreDef.name.toLowerCase()}>::MEM || addr.type == iss::address_type::PHYSICAL ||
addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) { addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) {
@@ -204,7 +206,7 @@ protected:
std::array<address_type, 4> addr_mode; std::array<address_type, 4> addr_mode;
bool interrupt_sim=false; uint64_t interrupt_sim=0;
<% <%
def fcsr = allRegs.find {it.name=='FCSR'} def fcsr = allRegs.find {it.name=='FCSR'}
if(fcsr != null) {%> if(fcsr != null) {%>

10
gen_input/templates/llvm/src-CORENAME.cpp.gtl
View File

@@ -70,17 +70,7 @@ def getRegisterAliasNames(){
%> %>
#include "util/ities.h" #include "util/ities.h"
#include <util/logging.h> #include <util/logging.h>
#include <elfio/elfio.hpp>
#include <iss/arch/${coreDef.name.toLowerCase()}.h> #include <iss/arch/${coreDef.name.toLowerCase()}.h>
#ifdef __cplusplus
extern "C" {
#endif
#include <ihex.h>
#ifdef __cplusplus
}
#endif
#include <cstdio> #include <cstdio>
#include <cstring> #include <cstring>
#include <fstream> #include <fstream>

4
gen_input/templates/llvm/vm-vm_CORENAME.cpp.gtl
View File

@@ -31,7 +31,7 @@
*******************************************************************************/ *******************************************************************************/
#include <iss/arch/${coreDef.name.toLowerCase()}.h> #include <iss/arch/${coreDef.name.toLowerCase()}.h>
#include <iss/arch/riscv_hart_msu_vp.h> #include <iss/arch/riscv_hart_m_p.h>
#include <iss/debugger/gdb_session.h> #include <iss/debugger/gdb_session.h>
#include <iss/debugger/server.h> #include <iss/debugger/server.h>
#include <iss/iss.h> #include <iss/iss.h>
@@ -57,7 +57,7 @@ using namespace ::llvm;
using namespace iss::arch; using namespace iss::arch;
using namespace iss::debugger; using namespace iss::debugger;
template <typename ARCH> class vm_impl : public vm::llvm::vm_base<ARCH> { template <typename ARCH> class vm_impl : public iss::llvm::vm_base<ARCH> {
public: public:
using super = typename iss::llvm::vm_base<ARCH>; using super = typename iss::llvm::vm_base<ARCH>;
using virt_addr_t = typename super::virt_addr_t; using virt_addr_t = typename super::virt_addr_t;

10
gen_input/templates/tcc/src-CORENAME.cpp.gtl
View File

@@ -70,17 +70,7 @@ def getRegisterAliasNames(){
%> %>
#include "util/ities.h" #include "util/ities.h"
#include <util/logging.h> #include <util/logging.h>
#include <elfio/elfio.hpp>
#include <iss/arch/${coreDef.name.toLowerCase()}.h> #include <iss/arch/${coreDef.name.toLowerCase()}.h>
#ifdef __cplusplus
extern "C" {
#endif
#include <ihex.h>
#ifdef __cplusplus
}
#endif
#include <cstdio> #include <cstdio>
#include <cstring> #include <cstring>
#include <fstream> #include <fstream>

6
gen_input/templates/tcc/vm-vm_CORENAME.cpp.gtl
View File

@@ -31,7 +31,7 @@
*******************************************************************************/ *******************************************************************************/
#include <iss/arch/${coreDef.name.toLowerCase()}.h> #include <iss/arch/${coreDef.name.toLowerCase()}.h>
#include <iss/arch/riscv_hart_msu_vp.h> #include <iss/arch/riscv_hart_m_p.h>
#include <iss/debugger/gdb_session.h> #include <iss/debugger/gdb_session.h>
#include <iss/debugger/server.h> #include <iss/debugger/server.h>
#include <iss/iss.h> #include <iss/iss.h>
@@ -184,8 +184,8 @@ private:
const std::array<InstructionDesriptor, ${instructions.size}> instr_descr = {{ const std::array<InstructionDesriptor, ${instructions.size}> instr_descr = {{
/* entries are: size, valid value, valid mask, function ptr */<%instructions.each{instr -> %> /* entries are: size, valid value, valid mask, function ptr */<%instructions.each{instr -> %>
/* instruction ${instr.instruction.name} */ /* instruction ${instr.instruction.name}, encoding '${instr.encoding}' */
{${instr.length}, ${instr.value}, ${instr.mask}, &this_class::__${generator.functionName(instr.name)}},<%}%> {${instr.length}, 0b${instr.value}, 0b${instr.mask}, &this_class::__${generator.functionName(instr.name)}},<%}%>
}}; }};
/* instruction definitions */<%instructions.eachWithIndex{instr, idx -> %> /* instruction definitions */<%instructions.eachWithIndex{instr, idx -> %>

625
incl/iss/arch/riscv_hart_msu_vp.h → incl/iss/arch/riscv_hart_m_p.h
View File

@@ -43,9 +43,9 @@
#ifndef FMT_HEADER_ONLY #ifndef FMT_HEADER_ONLY
#define FMT_HEADER_ONLY #define FMT_HEADER_ONLY
#endif #endif
#include <fmt/format.h>
#include <array> #include <array>
#include <elfio/elfio.hpp> #include <elfio/elfio.hpp>
#include <fmt/format.h>
#include <iomanip> #include <iomanip>
#include <sstream> #include <sstream>
#include <type_traits> #include <type_traits>
@@ -174,8 +174,6 @@ enum riscv_csr {
namespace { namespace {
std::array<const char, 4> lvl = {{'U', 'S', 'H', 'M'}};
std::array<const char *, 16> trap_str = {{"" std::array<const char *, 16> trap_str = {{""
"Instruction address misaligned", // 0 "Instruction address misaligned", // 0
"Instruction access fault", // 1 "Instruction access fault", // 1
@@ -233,14 +231,6 @@ enum {
ISA_U = 1 << 20 ISA_U = 1 << 20
}; };
struct vm_info {
int levels;
int idxbits;
int ptesize;
uint64_t ptbase;
bool is_active() { return levels; }
};
class trap_load_access_fault : public trap_access { class trap_load_access_fault : public trap_access {
public: public:
trap_load_access_fault(uint64_t badaddr) trap_load_access_fault(uint64_t badaddr)
@@ -251,28 +241,12 @@ public:
illegal_instruction_fault(uint64_t badaddr) illegal_instruction_fault(uint64_t badaddr)
: trap_access(2 << 16, badaddr) {} : trap_access(2 << 16, badaddr) {}
}; };
class trap_instruction_page_fault : public trap_access { } // namespace
public:
trap_instruction_page_fault(uint64_t badaddr)
: trap_access(12 << 16, badaddr) {}
};
class trap_load_page_fault : public trap_access {
public:
trap_load_page_fault(uint64_t badaddr)
: trap_access(13 << 16, badaddr) {}
};
class trap_store_page_fault : public trap_access {
public:
trap_store_page_fault(uint64_t badaddr)
: trap_access(15 << 16, badaddr) {}
};
}
template <typename BASE> class riscv_hart_msu_vp : public BASE { template <typename BASE> class riscv_hart_m_p : public BASE {
public: public:
using super = BASE; using super = BASE;
using this_class = riscv_hart_msu_vp<BASE>; using this_class = riscv_hart_m_p<BASE>;
using virt_addr_t = typename super::virt_addr_t;
using phys_addr_t = typename super::phys_addr_t; using phys_addr_t = typename super::phys_addr_t;
using reg_t = typename super::reg_t; using reg_t = typename super::reg_t;
using addr_t = typename super::addr_t; using addr_t = typename super::addr_t;
@@ -326,8 +300,8 @@ public:
static const reg_t mstatus_reset_val = 0; static const reg_t mstatus_reset_val = 0;
void write_mstatus(T val, unsigned priv_lvl) { void write_mstatus(T val) {
auto mask = get_mask(priv_lvl); auto mask = get_mask();
auto new_val = (mstatus.st.value & ~mask) | (val & mask); auto new_val = (mstatus.st.value & ~mask) | (val & mask);
mstatus = new_val; mstatus = new_val;
} }
@@ -336,156 +310,37 @@ public:
static constexpr T get_misa() { return (1UL << 30) | ISA_I | ISA_M | ISA_A | ISA_U | ISA_S | ISA_M; } static constexpr T get_misa() { return (1UL << 30) | ISA_I | ISA_M | ISA_A | ISA_U | ISA_S | ISA_M; }
static constexpr uint32_t get_mask(unsigned priv_lvl) { static constexpr uint32_t get_mask() {
#if __cplusplus < 201402L return 0x807ff9ddUL; // 0b1000 0000 0111 1111 1111 1001 1011 1011 // only machine mode is supported
return priv_lvl == PRIV_U ? 0x80000011UL : priv_lvl == PRIV_S ? 0x800de133UL : 0x807ff9ddUL;
#else
switch (priv_lvl) {
case PRIV_U: return 0x80000011UL; // 0b1000 0000 0000 0000 0000 0000 0001 0001
case PRIV_S: return 0x800de133UL; // 0b1000 0000 0000 1101 1110 0001 0011 0011
default: return 0x807ff9ddUL; // 0b1000 0000 0111 1111 1111 1001 1011 1011
}
#endif
}
static inline vm_info decode_vm_info(uint32_t state, T sptbr) {
if (state == PRIV_M) return {0, 0, 0, 0};
if (state <= PRIV_S)
switch (bit_sub<31, 1>(sptbr)) {
case 0: return {0, 0, 0, 0}; // off
case 1: return {2, 10, 4, bit_sub<0, 22>(sptbr) << PGSHIFT}; // SV32
default: abort();
}
abort();
return {0, 0, 0, 0}; // dummy
}
};
// specialization 64bit
template <typename T> class hart_state<T, typename std::enable_if<std::is_same<T, uint64_t>::value>::type> {
public:
BEGIN_BF_DECL(mstatus_t, T);
// SD bit is read-only and is set when either the FS or XS bits encode a Dirty state (i.e., SD=((FS==11) OR XS==11)))
BF_FIELD(SD, 63, 1);
// value of XLEN for S-mode
BF_FIELD(SXL, 34, 2);
// value of XLEN for U-mode
BF_FIELD(UXL, 32, 2);
// Trap SRET
BF_FIELD(TSR, 22, 1);
// Timeout Wait
BF_FIELD(TW, 21, 1);
// Trap Virtual Memory
BF_FIELD(TVM, 20, 1);
// Make eXecutable Readable
BF_FIELD(MXR, 19, 1);
// permit Supervisor User Memory access
BF_FIELD(SUM, 18, 1);
// Modify PRiVilege
BF_FIELD(MPRV, 17, 1);
// status of additional user-mode extensions and associated state, All off/None dirty or clean, some on/None dirty, some clean/Some dirty
BF_FIELD(XS, 15, 2);
// floating-point unit status Off/Initial/Clean/Dirty
BF_FIELD(FS, 13, 2);
// machine previous privilege
BF_FIELD(MPP, 11, 2);
// supervisor previous privilege
BF_FIELD(SPP, 8, 1);
// previous machine interrupt-enable
BF_FIELD(MPIE, 7, 1);
// previous supervisor interrupt-enable
BF_FIELD(SPIE, 5, 1);
// previous user interrupt-enable
BF_FIELD(UPIE, 4, 1);
// machine interrupt-enable
BF_FIELD(MIE, 3, 1);
// supervisor interrupt-enable
BF_FIELD(SIE, 1, 1);
// user interrupt-enable
BF_FIELD(UIE, 0, 1);
END_BF_DECL();
mstatus_t mstatus;
static const reg_t mstatus_reset_val = 0xa00000000;
void write_mstatus(T val, unsigned priv_lvl) {
T old_val = mstatus;
auto mask = get_mask(priv_lvl);
auto new_val = (old_val & ~mask) | (val & mask);
if ((new_val & mstatus.SXL.Mask) == 0) {
new_val |= old_val & mstatus.SXL.Mask;
}
if ((new_val & mstatus.UXL.Mask) == 0) {
new_val |= old_val & mstatus.UXL.Mask;
}
mstatus = new_val;
}
T satp;
static constexpr T get_misa() { return (2ULL << 62) | ISA_I | ISA_M | ISA_A | ISA_U | ISA_S | ISA_M; }
static constexpr T get_mask(unsigned priv_lvl) {
uint64_t ret;
switch (priv_lvl) {
case PRIV_U: ret = 0x8000000f00000011ULL;break; // 0b1...0 1111 0000 0000 0111 1111 1111 1001 1011 1011
case PRIV_S: ret = 0x8000000f000de133ULL;break; // 0b1...0 0011 0000 0000 0000 1101 1110 0001 0011 0011
default: ret = 0x8000000f007ff9ddULL;break; // 0b1...0 1111 0000 0000 0111 1111 1111 1001 1011 1011
}
return ret;
}
static inline vm_info decode_vm_info(uint32_t state, T sptbr) {
if (state == PRIV_M) return {0, 0, 0, 0};
if (state <= PRIV_S)
switch (bit_sub<60, 4>(sptbr)) {
case 0: return {0, 0, 0, 0}; // off
case 8: return {3, 9, 8, bit_sub<0, 44>(sptbr) << PGSHIFT};// SV39
case 9: return {4, 9, 8, bit_sub<0, 44>(sptbr) << PGSHIFT};// SV48
case 10: return {5, 9, 8, bit_sub<0, 44>(sptbr) << PGSHIFT};// SV57
case 11: return {6, 9, 8, bit_sub<0, 44>(sptbr) << PGSHIFT};// SV64
default: abort();
}
abort();
return {0, 0, 0, 0}; // dummy
} }
}; };
const typename super::reg_t PGSIZE = 1 << PGSHIFT; constexpr reg_t get_irq_mask() {
const typename super::reg_t PGMASK = PGSIZE - 1; return 0b101110111011; // only machine mode is supported
constexpr reg_t get_irq_mask(size_t mode) {
std::array<const reg_t, 4> m = {{
0b000100010001, // U mode
0b001100110011, // S mode
0,
0b101110111011 // M mode
}};
return m[mode];
} }
riscv_hart_msu_vp(); riscv_hart_m_p();
virtual ~riscv_hart_msu_vp() = default; virtual ~riscv_hart_m_p() = default;
void reset(uint64_t address) override; void reset(uint64_t address) override;
std::pair<uint64_t, bool> load_file(std::string name, int type = -1) override; std::pair<uint64_t, bool> load_file(std::string name, int type = -1) override;
virtual phys_addr_t virt2phys(const iss::addr_t &addr) override;
iss::status read(const address_type type, const access_type access, const uint32_t space, iss::status read(const address_type type, const access_type access, const uint32_t space,
const uint64_t addr, const unsigned length, uint8_t *const data) override; const uint64_t addr, const unsigned length, uint8_t *const data) override;
iss::status write(const address_type type, const access_type access, const uint32_t space, iss::status write(const address_type type, const access_type access, const uint32_t space,
const uint64_t addr, const unsigned length, const uint8_t *const data) override; const uint64_t addr, const unsigned length, const uint8_t *const data) override;
virtual uint64_t enter_trap(uint64_t flags) override { return riscv_hart_msu_vp::enter_trap(flags, fault_data); } virtual uint64_t enter_trap(uint64_t flags) override { return riscv_hart_m_p::enter_trap(flags, fault_data); }
virtual uint64_t enter_trap(uint64_t flags, uint64_t addr) override; virtual uint64_t enter_trap(uint64_t flags, uint64_t addr) override;
virtual uint64_t leave_trap(uint64_t flags) override; virtual uint64_t leave_trap(uint64_t flags) override;
void wait_until(uint64_t flags) override;
const reg_t& get_mhartid() const { return mhartid_reg; }
void set_mhartid(reg_t mhartid) { mhartid_reg = mhartid; };
void disass_output(uint64_t pc, const std::string instr) override { void disass_output(uint64_t pc, const std::string instr) override {
CLOG(INFO, disass) << fmt::format("0x{:016x} {:40} [p:{};s:0x{:x};c:{}]", CLOG(INFO, disass) << fmt::format("0x{:016x} {:40} [s:0x{:x};c:{}]",
pc, instr, lvl[this->reg.machine_state], (reg_t)state.mstatus, this->reg.icount); pc, instr, (reg_t)state.mstatus, this->reg.icount);
}; };
iss::instrumentation_if *get_instrumentation_if() override { return &instr_if; } iss::instrumentation_if *get_instrumentation_if() override { return &instr_if; }
@@ -493,7 +348,7 @@ public:
protected: protected:
struct riscv_instrumentation_if : public iss::instrumentation_if { struct riscv_instrumentation_if : public iss::instrumentation_if {
riscv_instrumentation_if(riscv_hart_msu_vp<BASE> &arch) riscv_instrumentation_if(riscv_hart_m_p<BASE> &arch)
: arch(arch) {} : arch(arch) {}
/** /**
* get the name of this architecture * get the name of this architecture
@@ -508,7 +363,7 @@ protected:
virtual void set_curr_instr_cycles(unsigned cycles) { arch.cycle_offset += cycles - 1; }; virtual void set_curr_instr_cycles(unsigned cycles) { arch.cycle_offset += cycles - 1; };
riscv_hart_msu_vp<BASE> &arch; riscv_hart_m_p<BASE> &arch;
}; };
friend struct riscv_instrumentation_if; friend struct riscv_instrumentation_if;
@@ -524,7 +379,6 @@ protected:
hart_state<reg_t> state; hart_state<reg_t> state;
uint64_t cycle_offset; uint64_t cycle_offset;
reg_t fault_data; reg_t fault_data;
std::array<vm_info, 2> vm;
uint64_t tohost = tohost_dflt; uint64_t tohost = tohost_dflt;
uint64_t fromhost = fromhost_dflt; uint64_t fromhost = fromhost_dflt;
unsigned to_host_wr_cnt = 0; unsigned to_host_wr_cnt = 0;
@@ -535,7 +389,6 @@ protected:
using csr_page_type = typename csr_type::page_type; using csr_page_type = typename csr_type::page_type;
mem_type mem; mem_type mem;
csr_type csr; csr_type csr;
void update_vm_info();
std::stringstream uart_buf; std::stringstream uart_buf;
std::unordered_map<reg_t, uint64_t> ptw; std::unordered_map<reg_t, uint64_t> ptw;
std::unordered_map<uint64_t, uint8_t> atomic_reservation; std::unordered_map<uint64_t, uint8_t> atomic_reservation;
@@ -551,17 +404,16 @@ private:
iss::status write_ie(unsigned addr, reg_t val); iss::status write_ie(unsigned addr, reg_t val);
iss::status read_ip(unsigned addr, reg_t &val); iss::status read_ip(unsigned addr, reg_t &val);
iss::status write_ip(unsigned addr, reg_t val); iss::status write_ip(unsigned addr, reg_t val);
iss::status read_satp(unsigned addr, reg_t &val); iss::status read_hartid(unsigned addr, reg_t &val);
iss::status write_satp(unsigned addr, reg_t val);
iss::status read_fcsr(unsigned addr, reg_t &val); reg_t mhartid_reg{0xF};
iss::status write_fcsr(unsigned addr, reg_t val);
protected: protected:
void check_interrupt(); void check_interrupt();
}; };
template <typename BASE> template <typename BASE>
riscv_hart_msu_vp<BASE>::riscv_hart_msu_vp() riscv_hart_m_p<BASE>::riscv_hart_m_p()
: state() : state()
, cycle_offset(0) , cycle_offset(0)
, instr_if(*this) { , instr_if(*this) {
@@ -572,43 +424,24 @@ riscv_hart_msu_vp<BASE>::riscv_hart_msu_vp()
for (unsigned addr = mcycle; addr <= hpmcounter31; ++addr) csr_wr_cb[addr] = nullptr; for (unsigned addr = mcycle; addr <= hpmcounter31; ++addr) csr_wr_cb[addr] = nullptr;
for (unsigned addr = mcycleh; addr <= hpmcounter31h; ++addr) csr_wr_cb[addr] = nullptr; for (unsigned addr = mcycleh; addr <= hpmcounter31h; ++addr) csr_wr_cb[addr] = nullptr;
// special handling // special handling
csr_rd_cb[time] = &riscv_hart_msu_vp<BASE>::read_time; csr_rd_cb[time] = &riscv_hart_m_p<BASE>::read_time;
csr_wr_cb[time] = nullptr; csr_wr_cb[time] = nullptr;
csr_rd_cb[timeh] = &riscv_hart_msu_vp<BASE>::read_time; csr_rd_cb[timeh] = &riscv_hart_m_p<BASE>::read_time;
csr_wr_cb[timeh] = nullptr; csr_wr_cb[timeh] = nullptr;
csr_rd_cb[mcycle] = &riscv_hart_msu_vp<BASE>::read_cycle; csr_rd_cb[mcycle] = &riscv_hart_m_p<BASE>::read_cycle;
csr_rd_cb[mcycleh] = &riscv_hart_msu_vp<BASE>::read_cycle; csr_rd_cb[mcycleh] = &riscv_hart_m_p<BASE>::read_cycle;
csr_rd_cb[minstret] = &riscv_hart_msu_vp<BASE>::read_cycle; csr_rd_cb[minstret] = &riscv_hart_m_p<BASE>::read_cycle;
csr_rd_cb[minstreth] = &riscv_hart_msu_vp<BASE>::read_cycle; csr_rd_cb[minstreth] = &riscv_hart_m_p<BASE>::read_cycle;
csr_rd_cb[mstatus] = &riscv_hart_msu_vp<BASE>::read_status; csr_rd_cb[mstatus] = &riscv_hart_m_p<BASE>::read_status;
csr_wr_cb[mstatus] = &riscv_hart_msu_vp<BASE>::write_status; csr_wr_cb[mstatus] = &riscv_hart_m_p<BASE>::write_status;
csr_rd_cb[sstatus] = &riscv_hart_msu_vp<BASE>::read_status; csr_rd_cb[mip] = &riscv_hart_m_p<BASE>::read_ip;
csr_wr_cb[sstatus] = &riscv_hart_msu_vp<BASE>::write_status; csr_wr_cb[mip] = &riscv_hart_m_p<BASE>::write_ip;
csr_rd_cb[ustatus] = &riscv_hart_msu_vp<BASE>::read_status; csr_rd_cb[mie] = &riscv_hart_m_p<BASE>::read_ie;
csr_wr_cb[ustatus] = &riscv_hart_msu_vp<BASE>::write_status; csr_wr_cb[mie] = &riscv_hart_m_p<BASE>::write_ie;
csr_rd_cb[mip] = &riscv_hart_msu_vp<BASE>::read_ip; csr_rd_cb[mhartid] = &riscv_hart_m_p<BASE>::read_hartid;
csr_wr_cb[mip] = &riscv_hart_msu_vp<BASE>::write_ip;
csr_rd_cb[sip] = &riscv_hart_msu_vp<BASE>::read_ip;
csr_wr_cb[sip] = &riscv_hart_msu_vp<BASE>::write_ip;
csr_rd_cb[uip] = &riscv_hart_msu_vp<BASE>::read_ip;
csr_wr_cb[uip] = &riscv_hart_msu_vp<BASE>::write_ip;
csr_rd_cb[mie] = &riscv_hart_msu_vp<BASE>::read_ie;
csr_wr_cb[mie] = &riscv_hart_msu_vp<BASE>::write_ie;
csr_rd_cb[sie] = &riscv_hart_msu_vp<BASE>::read_ie;
csr_wr_cb[sie] = &riscv_hart_msu_vp<BASE>::write_ie;
csr_rd_cb[uie] = &riscv_hart_msu_vp<BASE>::read_ie;
csr_wr_cb[uie] = &riscv_hart_msu_vp<BASE>::write_ie;
csr_rd_cb[satp] = &riscv_hart_msu_vp<BASE>::read_satp;
csr_wr_cb[satp] = &riscv_hart_msu_vp<BASE>::write_satp;
csr_rd_cb[fcsr] = &riscv_hart_msu_vp<BASE>::read_fcsr;
csr_wr_cb[fcsr] = &riscv_hart_msu_vp<BASE>::write_fcsr;
csr_rd_cb[fflags] = &riscv_hart_msu_vp<BASE>::read_fcsr;
csr_wr_cb[fflags] = &riscv_hart_msu_vp<BASE>::write_fcsr;
csr_rd_cb[frm] = &riscv_hart_msu_vp<BASE>::read_fcsr;
csr_wr_cb[frm] = &riscv_hart_msu_vp<BASE>::write_fcsr;
} }
template <typename BASE> std::pair<uint64_t, bool> riscv_hart_msu_vp<BASE>::load_file(std::string name, int type) { template <typename BASE> std::pair<uint64_t, bool> riscv_hart_m_p<BASE>::load_file(std::string name, int type) {
FILE *fp = fopen(name.c_str(), "r"); FILE *fp = fopen(name.c_str(), "r");
if (fp) { if (fp) {
std::array<char, 5> buf; std::array<char, 5> buf;
@@ -653,7 +486,7 @@ template <typename BASE> std::pair<uint64_t, bool> riscv_hart_msu_vp<BASE>::load
} }
template <typename BASE> template <typename BASE>
iss::status riscv_hart_msu_vp<BASE>::read(const address_type type, const access_type access, const uint32_t space, iss::status riscv_hart_m_p<BASE>::read(const address_type type, const access_type access, const uint32_t space,
const uint64_t addr, const unsigned length, uint8_t *const data) { const uint64_t addr, const unsigned length, uint8_t *const data) {
#ifndef NDEBUG #ifndef NDEBUG
if (access && iss::access_type::DEBUG) { if (access && iss::access_type::DEBUG) {
@@ -674,17 +507,6 @@ iss::status riscv_hart_msu_vp<BASE>::read(const address_type type, const access_
return iss::Err; return iss::Err;
} }
try { try {
if (unlikely((addr & ~PGMASK) != ((addr + length - 1) & ~PGMASK))) { // we may cross a page boundary
vm_info vm = hart_state<reg_t>::decode_vm_info(this->reg.machine_state, state.satp);
if (vm.levels != 0) { // VM is active
auto split_addr = (addr + length) & ~PGMASK;
auto len1 = split_addr - addr;
auto res = read(type, access, space, addr, len1, data);
if (res == iss::Ok)
res = read(type, access, space, split_addr, length - len1, data + len1);
return res;
}
}
auto res = type==iss::address_type::PHYSICAL? auto res = type==iss::address_type::PHYSICAL?
read_mem( BASE::v2p(phys_addr_t{access, space, addr}), length, data): read_mem( BASE::v2p(phys_addr_t{access, space, addr}), length, data):
read_mem( BASE::v2p(iss::addr_t{access, type, space, addr}), length, data); read_mem( BASE::v2p(iss::addr_t{access, type, space, addr}), length, data);
@@ -701,18 +523,7 @@ iss::status riscv_hart_msu_vp<BASE>::read(const address_type type, const access_
} break; } break;
case traits<BASE>::FENCE: { case traits<BASE>::FENCE: {
if ((addr + length) > mem.size()) return iss::Err; if ((addr + length) > mem.size()) return iss::Err;
switch (addr) {
case 2: // SFENCE:VMA lower
case 3: { // SFENCE:VMA upper
auto tvm = state.mstatus.TVM;
if (this->reg.machine_state == PRIV_S & tvm != 0) {
this->reg.trap_state = (1 << 31) | (2 << 16);
this->fault_data = this->reg.PC;
return iss::Err;
}
return iss::Ok; return iss::Ok;
}
}
} break; } break;
case traits<BASE>::RES: { case traits<BASE>::RES: {
auto it = atomic_reservation.find(addr); auto it = atomic_reservation.find(addr);
@@ -733,7 +544,7 @@ iss::status riscv_hart_msu_vp<BASE>::read(const address_type type, const access_
} }
template <typename BASE> template <typename BASE>
iss::status riscv_hart_msu_vp<BASE>::write(const address_type type, const access_type access, const uint32_t space, iss::status riscv_hart_m_p<BASE>::write(const address_type type, const access_type access, const uint32_t space,
const uint64_t addr, const unsigned length, const uint8_t *const data) { const uint64_t addr, const unsigned length, const uint8_t *const data) {
#ifndef NDEBUG #ifndef NDEBUG
const char *prefix = (access && iss::access_type::DEBUG) ? "debug " : ""; const char *prefix = (access && iss::access_type::DEBUG) ? "debug " : "";
@@ -768,17 +579,6 @@ iss::status riscv_hart_msu_vp<BASE>::write(const address_type type, const access
return iss::Err; return iss::Err;
} }
try { try {
if (unlikely((addr & ~PGMASK) != ((addr + length - 1) & ~PGMASK))) { // we may cross a page boundary
vm_info vm = hart_state<reg_t>::decode_vm_info(this->reg.machine_state, state.satp);
if (vm.levels != 0) { // VM is active
auto split_addr = (addr + length) & ~PGMASK;
auto len1 = split_addr - addr;
auto res = write(type, access, space, addr, len1, data);
if (res == iss::Ok)
res = write(type, access, space, split_addr, length - len1, data + len1);
return res;
}
}
auto res = type==iss::address_type::PHYSICAL? auto res = type==iss::address_type::PHYSICAL?
write_mem(phys_addr_t{access, space, addr}, length, data): write_mem(phys_addr_t{access, space, addr}, length, data):
write_mem(BASE::v2p(iss::addr_t{access, type, space, addr}), length, data); write_mem(BASE::v2p(iss::addr_t{access, type, space, addr}), length, data);
@@ -833,11 +633,6 @@ iss::status riscv_hart_msu_vp<BASE>::write(const address_type type, const access
case 3: { case 3: {
ptw.clear(); ptw.clear();
auto tvm = state.mstatus.TVM; auto tvm = state.mstatus.TVM;
if (this->reg.machine_state == PRIV_S & tvm != 0) {
this->reg.trap_state = (1 << 31) | (2 << 16);
this->fault_data = this->reg.PC;
return iss::Err;
}
return iss::Ok; return iss::Ok;
} }
} }
@@ -855,8 +650,10 @@ iss::status riscv_hart_msu_vp<BASE>::write(const address_type type, const access
} }
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_csr(unsigned addr, reg_t &val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::read_csr(unsigned addr, reg_t &val) {
if (addr >= csr.size()) return iss::Err; if (addr >= csr.size()) return iss::Err;
auto req_priv_lvl = (addr >> 8) & 0x3;
if (this->reg.machine_state < req_priv_lvl) throw illegal_instruction_fault(this->fault_data);
auto it = csr_rd_cb.find(addr); auto it = csr_rd_cb.find(addr);
if (it == csr_rd_cb.end()) { if (it == csr_rd_cb.end()) {
val = csr[addr & csr.page_addr_mask]; val = csr[addr & csr.page_addr_mask];
@@ -867,8 +664,13 @@ template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_csr(unsigned
return (this->*f)(addr, val); return (this->*f)(addr, val);
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::write_csr(unsigned addr, reg_t val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::write_csr(unsigned addr, reg_t val) {
if (addr >= csr.size()) return iss::Err; if (addr >= csr.size()) return iss::Err;
auto req_priv_lvl = (addr >> 8) & 0x3;
if (this->reg.machine_state < req_priv_lvl)
throw illegal_instruction_fault(this->fault_data);
if((addr&0xc00)==0xc00)
throw illegal_instruction_fault(this->fault_data);
auto it = csr_wr_cb.find(addr); auto it = csr_wr_cb.find(addr);
if (it == csr_wr_cb.end()) { if (it == csr_wr_cb.end()) {
csr[addr & csr.page_addr_mask] = val; csr[addr & csr.page_addr_mask] = val;
@@ -879,7 +681,7 @@ template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::write_csr(unsigned
return (this->*f)(addr, val); return (this->*f)(addr, val);
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_cycle(unsigned addr, reg_t &val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::read_cycle(unsigned addr, reg_t &val) {
auto cycle_val = this->reg.icount + cycle_offset; auto cycle_val = this->reg.icount + cycle_offset;
if (addr == mcycle) { if (addr == mcycle) {
val = static_cast<reg_t>(cycle_val); val = static_cast<reg_t>(cycle_val);
@@ -890,7 +692,7 @@ template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_cycle(unsigne
return iss::Ok; return iss::Ok;
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_time(unsigned addr, reg_t &val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::read_time(unsigned addr, reg_t &val) {
uint64_t time_val = (this->reg.icount + cycle_offset) / (100000000 / 32768 - 1); //-> ~3052; uint64_t time_val = (this->reg.icount + cycle_offset) / (100000000 / 32768 - 1); //-> ~3052;
if (addr == time) { if (addr == time) {
val = static_cast<reg_t>(time_val); val = static_cast<reg_t>(time_val);
@@ -901,117 +703,51 @@ template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_time(unsigned
return iss::Ok; return iss::Ok;
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_status(unsigned addr, reg_t &val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::read_status(unsigned addr, reg_t &val) {
auto req_priv_lvl = addr >> 8; val = state.mstatus & hart_state<reg_t>::get_mask();
if (this->reg.machine_state < req_priv_lvl) throw illegal_instruction_fault(this->fault_data);
val = state.mstatus & hart_state<reg_t>::get_mask(req_priv_lvl);
return iss::Ok; return iss::Ok;
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::write_status(unsigned addr, reg_t val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::write_status(unsigned addr, reg_t val) {
auto req_priv_lvl = addr >> 8; state.write_mstatus(val);
if (this->reg.machine_state < req_priv_lvl) throw illegal_instruction_fault(this->fault_data);
state.write_mstatus(val, req_priv_lvl);
check_interrupt(); check_interrupt();
update_vm_info();
return iss::Ok; return iss::Ok;
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_ie(unsigned addr, reg_t &val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::read_ie(unsigned addr, reg_t &val) {
auto req_priv_lvl = addr >> 8;
if (this->reg.machine_state < req_priv_lvl) throw illegal_instruction_fault(this->fault_data);
val = csr[mie]; val = csr[mie];
if (addr < mie) val &= csr[mideleg]; val &= csr[mideleg];
if (addr < sie) val &= csr[sideleg];
return iss::Ok; return iss::Ok;
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::write_ie(unsigned addr, reg_t val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::read_hartid(unsigned addr, reg_t &val) {
auto req_priv_lvl = addr >> 8; val = mhartid_reg;
if (this->reg.machine_state < req_priv_lvl) throw illegal_instruction_fault(this->fault_data); return iss::Ok;
auto mask = get_irq_mask(req_priv_lvl); }
template <typename BASE> iss::status riscv_hart_m_p<BASE>::write_ie(unsigned addr, reg_t val) {
auto mask = get_irq_mask();
csr[mie] = (csr[mie] & ~mask) | (val & mask); csr[mie] = (csr[mie] & ~mask) | (val & mask);
check_interrupt(); check_interrupt();
return iss::Ok; return iss::Ok;
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_ip(unsigned addr, reg_t &val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::read_ip(unsigned addr, reg_t &val) {
auto req_priv_lvl = addr >> 8;
if (this->reg.machine_state < req_priv_lvl) throw illegal_instruction_fault(this->fault_data);
val = csr[mip]; val = csr[mip];
if (addr < mip) val &= csr[mideleg]; val &= csr[mideleg];
if (addr < sip) val &= csr[sideleg];
return iss::Ok; return iss::Ok;
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::write_ip(unsigned addr, reg_t val) { template <typename BASE> iss::status riscv_hart_m_p<BASE>::write_ip(unsigned addr, reg_t val) {
auto req_priv_lvl = addr >> 8; auto mask = get_irq_mask();
if (this->reg.machine_state < req_priv_lvl) throw illegal_instruction_fault(this->fault_data);
auto mask = get_irq_mask(req_priv_lvl);
mask &= ~(1 << 7); // MTIP is read only mask &= ~(1 << 7); // MTIP is read only
csr[mip] = (csr[mip] & ~mask) | (val & mask); csr[mip] = (csr[mip] & ~mask) | (val & mask);
check_interrupt(); check_interrupt();
return iss::Ok; return iss::Ok;
} }
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_satp(unsigned addr, reg_t &val) {
reg_t tvm = state.mstatus.TVM;
if (this->reg.machine_state == PRIV_S & tvm != 0) {
this->reg.trap_state = (1 << 31) | (2 << 16);
this->fault_data = this->reg.PC;
return iss::Err;
}
val = state.satp;
return iss::Ok;
}
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::write_satp(unsigned addr, reg_t val) {
reg_t tvm = state.mstatus.TVM;
if (this->reg.machine_state == PRIV_S & tvm != 0) {
this->reg.trap_state = (1 << 31) | (2 << 16);
this->fault_data = this->reg.PC;
return iss::Err;
}
state.satp = val;
update_vm_info();
return iss::Ok;
}
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::read_fcsr(unsigned addr, reg_t &val) {
switch (addr) {
case 1: // fflags, 4:0
val = bit_sub<0, 5>(this->get_fcsr());
break;
case 2: // frm, 7:5
val = bit_sub<5, 3>(this->get_fcsr());
break;
case 3: // fcsr
val = this->get_fcsr();
break;
default:
return iss::Err;
}
return iss::Ok;
}
template <typename BASE> iss::status riscv_hart_msu_vp<BASE>::write_fcsr(unsigned addr, reg_t val) {
switch (addr) {
case 1: // fflags, 4:0
this->set_fcsr((this->get_fcsr() & 0xffffffe0) | (val & 0x1f));
break;
case 2: // frm, 7:5
this->set_fcsr((this->get_fcsr() & 0xffffff1f) | ((val & 0x7) << 5));
break;
case 3: // fcsr
this->set_fcsr(val & 0xff);
break;
default:
return iss::Err;
}
return iss::Ok;
}
template <typename BASE> template <typename BASE>
iss::status riscv_hart_msu_vp<BASE>::read_mem(phys_addr_t paddr, unsigned length, uint8_t *const data) { iss::status riscv_hart_m_p<BASE>::read_mem(phys_addr_t paddr, unsigned length, uint8_t *const data) {
if ((paddr.val + length) > mem.size()) return iss::Err; if ((paddr.val + length) > mem.size()) return iss::Err;
switch (paddr.val) { switch (paddr.val) {
case 0x0200BFF8: { // CLINT base, mtime reg case 0x0200BFF8: { // CLINT base, mtime reg
@@ -1036,7 +772,7 @@ iss::status riscv_hart_msu_vp<BASE>::read_mem(phys_addr_t paddr, unsigned length
} }
template <typename BASE> template <typename BASE>
iss::status riscv_hart_msu_vp<BASE>::write_mem(phys_addr_t paddr, unsigned length, const uint8_t *const data) { iss::status riscv_hart_m_p<BASE>::write_mem(phys_addr_t paddr, unsigned length, const uint8_t *const data) {
if ((paddr.val + length) > mem.size()) return iss::Err; if ((paddr.val + length) > mem.size()) return iss::Err;
switch (paddr.val) { switch (paddr.val) {
case 0x10013000: // UART0 base, TXFIFO reg case 0x10013000: // UART0 base, TXFIFO reg
@@ -1068,10 +804,9 @@ iss::status riscv_hart_msu_vp<BASE>::write_mem(phys_addr_t paddr, unsigned lengt
std::copy(data, data + length, p.data() + (paddr.val & mem.page_addr_mask)); std::copy(data, data + length, p.data() + (paddr.val & mem.page_addr_mask));
// tohost handling in case of riscv-test // tohost handling in case of riscv-test
if (paddr.access && iss::access_type::FUNC) { if (paddr.access && iss::access_type::FUNC) {
auto tohost_upper = (traits<BASE>::XLEN == 32 && paddr.val == (tohost + 4)) || auto tohost_upper = (traits<BASE>::XLEN == 32 && paddr.val == (tohost + 4));
(traits<BASE>::XLEN == 64 && paddr.val == tohost);
auto tohost_lower = auto tohost_lower =
(traits<BASE>::XLEN == 32 && paddr.val == tohost) || (traits<BASE>::XLEN == 64 && paddr.val == tohost); (traits<BASE>::XLEN == 32 && paddr.val == tohost);
if (tohost_lower || tohost_upper) { if (tohost_lower || tohost_upper) {
uint64_t hostvar = *reinterpret_cast<uint64_t *>(p.data() + (tohost & mem.page_addr_mask)); uint64_t hostvar = *reinterpret_cast<uint64_t *>(p.data() + (tohost & mem.page_addr_mask));
if (tohost_upper || (tohost_lower && to_host_wr_cnt > 0)) { if (tohost_upper || (tohost_lower && to_host_wr_cnt > 0)) {
@@ -1102,8 +837,7 @@ iss::status riscv_hart_msu_vp<BASE>::write_mem(phys_addr_t paddr, unsigned lengt
} }
} else if (tohost_lower) } else if (tohost_lower)
to_host_wr_cnt++; to_host_wr_cnt++;
} else if ((traits<BASE>::XLEN == 32 && paddr.val == fromhost + 4) || } else if (traits<BASE>::XLEN == 32 && paddr.val == fromhost + 4) {
(traits<BASE>::XLEN == 64 && paddr.val == fromhost)) {
uint64_t fhostvar = *reinterpret_cast<uint64_t *>(p.data() + (fromhost & mem.page_addr_mask)); uint64_t fhostvar = *reinterpret_cast<uint64_t *>(p.data() + (fromhost & mem.page_addr_mask));
*reinterpret_cast<uint64_t *>(p.data() + (tohost & mem.page_addr_mask)) = fhostvar; *reinterpret_cast<uint64_t *>(p.data() + (tohost & mem.page_addr_mask)) = fhostvar;
} }
@@ -1113,43 +847,23 @@ iss::status riscv_hart_msu_vp<BASE>::write_mem(phys_addr_t paddr, unsigned lengt
return iss::Ok; return iss::Ok;
} }
template <typename BASE> inline void riscv_hart_msu_vp<BASE>::reset(uint64_t address) { template <typename BASE> inline void riscv_hart_m_p<BASE>::reset(uint64_t address) {
BASE::reset(address); BASE::reset(address);
state.mstatus = hart_state<reg_t>::mstatus_reset_val; state.mstatus = hart_state<reg_t>::mstatus_reset_val;
update_vm_info();
} }
template <typename BASE> inline void riscv_hart_msu_vp<BASE>::update_vm_info() { template <typename BASE> void riscv_hart_m_p<BASE>::check_interrupt() {
vm[1] = hart_state<reg_t>::decode_vm_info(this->reg.machine_state, state.satp);
BASE::addr_mode[3]=BASE::addr_mode[2] = vm[1].is_active()? iss::address_type::VIRTUAL : iss::address_type::PHYSICAL;
if (state.mstatus.MPRV)
vm[0] = hart_state<reg_t>::decode_vm_info(state.mstatus.MPP, state.satp);
else
vm[0] = vm[1];
BASE::addr_mode[1] = BASE::addr_mode[0]=vm[0].is_active() ? iss::address_type::VIRTUAL : iss::address_type::PHYSICAL;
ptw.clear();
}
template <typename BASE> void riscv_hart_msu_vp<BASE>::check_interrupt() {
auto status = state.mstatus;
auto ip = csr[mip];
auto ie = csr[mie];
auto ideleg = csr[mideleg]; auto ideleg = csr[mideleg];
// Multiple simultaneous interrupts and traps at the same privilege level are // Multiple simultaneous interrupts and traps at the same privilege level are
// handled in the following decreasing priority order: // handled in the following decreasing priority order:
// external interrupts, software interrupts, timer interrupts, then finally // external interrupts, software interrupts, timer interrupts, then finally
// any synchronous traps. // any synchronous traps.
auto ena_irq = ip & ie; auto ena_irq = csr[mip] & csr[mie];
bool mie = state.mstatus.MIE; bool mie = state.mstatus.MIE;
auto m_enabled = this->reg.machine_state < PRIV_M || (this->reg.machine_state == PRIV_M && mie); auto m_enabled = this->reg.machine_state < PRIV_M || (this->reg.machine_state == PRIV_M && mie);
auto enabled_interrupts = m_enabled ? ena_irq & ~ideleg : 0; auto enabled_interrupts = m_enabled ? ena_irq & ~ideleg : 0;
if (enabled_interrupts == 0) {
auto sie = state.mstatus.SIE;
auto s_enabled = this->reg.machine_state < PRIV_S || (this->reg.machine_state == PRIV_S && sie);
enabled_interrupts = s_enabled ? ena_irq & ideleg : 0;
}
if (enabled_interrupts != 0) { if (enabled_interrupts != 0) {
int res = 0; int res = 0;
while ((enabled_interrupts & 1) == 0) enabled_interrupts >>= 1, res++; while ((enabled_interrupts & 1) == 0) enabled_interrupts >>= 1, res++;
@@ -1157,130 +871,23 @@ template <typename BASE> void riscv_hart_msu_vp<BASE>::check_interrupt() {
} }
} }
template <typename BASE> template <typename BASE> uint64_t riscv_hart_m_p<BASE>::enter_trap(uint64_t flags, uint64_t addr) {
typename riscv_hart_msu_vp<BASE>::phys_addr_t riscv_hart_msu_vp<BASE>::virt2phys(const iss::addr_t &addr) {
const auto type = addr.access & iss::access_type::FUNC;
auto it = ptw.find(addr.val >> PGSHIFT);
if (it != ptw.end()) {
const reg_t pte = it->second;
const reg_t ad = PTE_A | (type == iss::access_type::WRITE) * PTE_D;
#ifdef RISCV_ENABLE_DIRTY
// set accessed and possibly dirty bits.
*(uint32_t *)ppte |= ad;
return {addr.getAccessType(), addr.space, (pte & (~PGMASK)) | (addr.val & PGMASK)};
#else
// take exception if access or possibly dirty bit is not set.
if ((pte & ad) == ad)
return {addr.access, addr.space, (pte & (~PGMASK)) | (addr.val & PGMASK)};
else
ptw.erase(it); // throw an exception
#endif
} else {
uint32_t mode = type != iss::access_type::FETCH && state.mstatus.MPRV ? // MPRV
state.mstatus.MPP :
this->reg.machine_state;
const vm_info &vm = this->vm[static_cast<uint16_t>(type) / 2];
const bool s_mode = mode == PRIV_S;
const bool sum = state.mstatus.SUM;
const bool mxr = state.mstatus.MXR;
// verify bits xlen-1:va_bits-1 are all equal
const int va_bits = PGSHIFT + vm.levels * vm.idxbits;
const reg_t mask = (reg_t(1) << (traits<BASE>::XLEN > -(va_bits - 1))) - 1;
const reg_t masked_msbs = (addr.val >> (va_bits - 1)) & mask;
const int levels = (masked_msbs != 0 && masked_msbs != mask) ? 0 : vm.levels;
reg_t base = vm.ptbase;
for (int i = levels - 1; i >= 0; i--) {
const int ptshift = i * vm.idxbits;
const reg_t idx = (addr.val >> (PGSHIFT + ptshift)) & ((1 << vm.idxbits) - 1);
// check that physical address of PTE is legal
reg_t pte = 0;
const uint8_t res = this->read(iss::address_type::PHYSICAL, addr.access,
traits<BASE>::MEM, base + idx * vm.ptesize, vm.ptesize, (uint8_t *)&pte);
if (res != 0) throw trap_load_access_fault(addr.val);
const reg_t ppn = pte >> PTE_PPN_SHIFT;
if (PTE_TABLE(pte)) { // next level of page table
base = ppn << PGSHIFT;
} else if ((pte & PTE_U) ? s_mode && (type == iss::access_type::FETCH || !sum) : !s_mode) {
break;
} else if (!(pte & PTE_V) || (!(pte & PTE_R) && (pte & PTE_W))) {
break;
} else if (type == iss::access_type::FETCH
? !(pte & PTE_X)
: type == iss::access_type::READ ? !(pte & PTE_R) && !(mxr && (pte & PTE_X))
: !((pte & PTE_R) && (pte & PTE_W))) {
break;
} else if ((ppn & ((reg_t(1) << ptshift) - 1)) != 0) {
break;
} else {
const reg_t ad = PTE_A | ((type == iss::access_type::WRITE) * PTE_D);
#ifdef RISCV_ENABLE_DIRTY
// set accessed and possibly dirty bits.
*(uint32_t *)ppte |= ad;
#else
// take exception if access or possibly dirty bit is not set.
if ((pte & ad) != ad) break;
#endif
// for superpage mappings, make a fake leaf PTE for the TLB's benefit.
const reg_t vpn = addr.val >> PGSHIFT;
const reg_t value = (ppn | (vpn & ((reg_t(1) << ptshift) - 1))) << PGSHIFT;
const reg_t offset = addr.val & PGMASK;
ptw[vpn] = value | (pte & 0xff);
return {addr.access, addr.space, value | offset};
}
}
}
switch (type) {
case access_type::FETCH:
this->fault_data = addr.val;
throw trap_instruction_page_fault(addr.val);
case access_type::READ:
this->fault_data = addr.val;
throw trap_load_page_fault(addr.val);
case access_type::WRITE:
this->fault_data = addr.val;
throw trap_store_page_fault(addr.val);
default:
abort();
}
}
template <typename BASE> uint64_t riscv_hart_msu_vp<BASE>::enter_trap(uint64_t flags, uint64_t addr) {
auto cur_priv = this->reg.machine_state;
// flags are ACTIVE[31:31], CAUSE[30:16], TRAPID[15:0] // flags are ACTIVE[31:31], CAUSE[30:16], TRAPID[15:0]
// calculate and write mcause val // calculate and write mcause val
auto trap_id = bit_sub<0, 16>(flags); auto trap_id = bit_sub<0, 16>(flags);
auto cause = bit_sub<16, 15>(flags); auto cause = bit_sub<16, 15>(flags);
if (trap_id == 0 && cause == 11) cause = 0x8 + cur_priv; // adjust environment call cause if (trap_id == 0 && cause == 11) cause = 0x8 + PRIV_M; // adjust environment call cause
// calculate effective privilege level // calculate effective privilege level
auto new_priv = PRIV_M;
if (trap_id == 0) { // exception if (trap_id == 0) { // exception
if (cur_priv != PRIV_M && ((csr[medeleg] >> cause) & 0x1) != 0)
new_priv = (csr[sedeleg] >> cause) & 0x1 ? PRIV_U : PRIV_S;
// store ret addr in xepc register // store ret addr in xepc register
csr[uepc | (new_priv << 8)] = static_cast<reg_t>(addr); // store actual address instruction of exception csr[mepc] = static_cast<reg_t>(addr); // store actual address instruction of exception
/* csr[mtval] = fault_data;
* write mtval if new_priv=M_MODE, spec says:
* When a hardware breakpoint is triggered, or an instruction-fetch, load,
* or store address-misaligned,
* access, or page-fault exception occurs, mtval is written with the
* faulting effective address.
*/
csr[utval | (new_priv << 8)] = fault_data;
fault_data = 0; fault_data = 0;
} else { } else {
if (cur_priv != PRIV_M && ((csr[mideleg] >> cause) & 0x1) != 0) csr[mepc] = this->reg.NEXT_PC; // store next address if interrupt
new_priv = (csr[sideleg] >> cause) & 0x1 ? PRIV_U : PRIV_S;
csr[uepc | (new_priv << 8)] = this->reg.NEXT_PC; // store next address if interrupt
this->reg.pending_trap = 0; this->reg.pending_trap = 0;
} }
size_t adr = ucause | (new_priv << 8); csr[mcause] = (trap_id << 31) + cause;
csr[adr] = (trap_id << 31) + cause;
// update mstatus // update mstatus
// xPP field of mstatus is written with the active privilege mode at the time // xPP field of mstatus is written with the active privilege mode at the time
// of the trap; the x PIE field of mstatus // of the trap; the x PIE field of mstatus
@@ -1288,92 +895,50 @@ template <typename BASE> uint64_t riscv_hart_msu_vp<BASE>::enter_trap(uint64_t f
// the trap; and the x IE field of mstatus // the trap; and the x IE field of mstatus
// is cleared // is cleared
// store the actual privilege level in yPP and store interrupt enable flags // store the actual privilege level in yPP and store interrupt enable flags
switch (new_priv) { state.mstatus.MPP = PRIV_M;
case PRIV_M:
state.mstatus.MPP = cur_priv;
state.mstatus.MPIE = state.mstatus.MIE; state.mstatus.MPIE = state.mstatus.MIE;
state.mstatus.MIE = false; state.mstatus.MIE = false;
break;
case PRIV_S:
state.mstatus.SPP = cur_priv;
state.mstatus.SPIE = state.mstatus.SIE;
state.mstatus.SIE = false;
break;
case PRIV_U:
state.mstatus.UPIE = state.mstatus.UIE;
state.mstatus.UIE = false;
break;
default:
break;
}
// get trap vector // get trap vector
auto ivec = csr[utvec | (new_priv << 8)]; auto ivec = csr[mtvec];
// calculate addr// set NEXT_PC to trap addressess to jump to based on MODE // calculate addr// set NEXT_PC to trap addressess to jump to based on MODE
// bits in mtvec // bits in mtvec
this->reg.NEXT_PC = ivec & ~0x1UL; this->reg.NEXT_PC = ivec & ~0x1UL;
if ((ivec & 0x1) == 1 && trap_id != 0) this->reg.NEXT_PC += 4 * cause; if ((ivec & 0x1) == 1 && trap_id != 0) this->reg.NEXT_PC += 4 * cause;
// reset trap state // reset trap state
this->reg.machine_state = new_priv; this->reg.machine_state = PRIV_M;
this->reg.trap_state = 0; this->reg.trap_state = 0;
std::array<char, 32> buffer; std::array<char, 32> buffer;
sprintf(buffer.data(), "0x%016lx", addr); sprintf(buffer.data(), "0x%016lx", addr);
if((flags&0xffffffff) != 0xffffffff) if((flags&0xffffffff) != 0xffffffff)
CLOG(INFO, disass) << (trap_id ? "Interrupt" : "Trap") << " with cause '" CLOG(INFO, disass) << (trap_id ? "Interrupt" : "Trap") << " with cause '"
<< (trap_id ? irq_str[cause] : trap_str[cause]) << "' (" << cause << ")" << (trap_id ? irq_str[cause] : trap_str[cause]) << "' (" << cause << ")"
<< " at address " << buffer.data() << " occurred, changing privilege level from " << " at address " << buffer.data() << " occurred";
<< lvl[cur_priv] << " to " << lvl[new_priv];
update_vm_info();
return this->reg.NEXT_PC; return this->reg.NEXT_PC;
} }
template <typename BASE> uint64_t riscv_hart_msu_vp<BASE>::leave_trap(uint64_t flags) { template <typename BASE> uint64_t riscv_hart_m_p<BASE>::leave_trap(uint64_t flags) {
auto cur_priv = this->reg.machine_state; auto cur_priv = this->reg.machine_state;
auto inst_priv = flags & 0x3; auto inst_priv = flags & 0x3;
auto status = state.mstatus; auto status = state.mstatus;
auto tsr = state.mstatus.TSR;
if (cur_priv == PRIV_S && inst_priv == PRIV_S && tsr != 0) {
this->reg.trap_state = (1 << 31) | (2 << 16);
this->fault_data = this->reg.PC;
return this->reg.PC;
}
// pop the relevant lower-privilege interrupt enable and privilege mode stack // pop the relevant lower-privilege interrupt enable and privilege mode stack
// clear respective yIE // clear respective yIE
switch (inst_priv) { if (inst_priv == PRIV_M) {
case PRIV_M:
this->reg.machine_state = state.mstatus.MPP; this->reg.machine_state = state.mstatus.MPP;
state.mstatus.MPP = 0; // clear mpp to U mode state.mstatus.MPP = 0; // clear mpp to U mode
state.mstatus.MIE = state.mstatus.MPIE; state.mstatus.MIE = state.mstatus.MPIE;
break; } else {
case PRIV_S: CLOG(ERROR, disass) << "Unsupported mode:" << inst_priv;
this->reg.machine_state = state.mstatus.SPP;
state.mstatus.SPP = 0; // clear spp to U mode
state.mstatus.SIE = state.mstatus.SPIE;
break;
case PRIV_U:
this->reg.machine_state = 0;
state.mstatus.UIE = state.mstatus.UPIE;
break;
} }
// sets the pc to the value stored in the x epc register. // sets the pc to the value stored in the x epc register.
this->reg.NEXT_PC = csr[uepc | inst_priv << 8]; this->reg.NEXT_PC = csr[mepc];
CLOG(INFO, disass) << "Executing xRET , changing privilege level from " << lvl[cur_priv] << " to " CLOG(INFO, disass) << "Executing xRET";
<< lvl[this->reg.machine_state];
update_vm_info();
return this->reg.NEXT_PC; return this->reg.NEXT_PC;
} }
template <typename BASE> void riscv_hart_msu_vp<BASE>::wait_until(uint64_t flags) { } // namespace arch
auto status = state.mstatus; } // namespace iss
auto tw = status.TW;
if (this->reg.machine_state == PRIV_S && tw != 0) {
this->reg.trap_state = (1 << 31) | (2 << 16);
this->fault_data = this->reg.PC;
}
}
}
}
#endif /* _RISCV_CORE_H_ */ #endif /* _RISCV_CORE_H_ */

316
incl/iss/arch/rv32gc.h
View File

@@ -1,316 +0,0 @@
/*******************************************************************************
* Copyright (C) 2017, 2018 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*******************************************************************************/
#ifndef _RV32GC_H_
#define _RV32GC_H_
#include <array>
#include <iss/arch/traits.h>
#include <iss/arch_if.h>
#include <iss/vm_if.h>
namespace iss {
namespace arch {
struct rv32gc;
template <> struct traits<rv32gc> {
constexpr static char const* const core_type = "RV32GC";
static constexpr std::array<const char*, 66> reg_names{
{"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7", "x8", "x9", "x10", "x11", "x12", "x13", "x14", "x15", "x16", "x17", "x18", "x19", "x20", "x21", "x22", "x23", "x24", "x25", "x26", "x27", "x28", "x29", "x30", "x31", "pc", "f0", "f1", "f2", "f3", "f4", "f5", "f6", "f7", "f8", "f9", "f10", "f11", "f12", "f13", "f14", "f15", "f16", "f17", "f18", "f19", "f20", "f21", "f22", "f23", "f24", "f25", "f26", "f27", "f28", "f29", "f30", "f31", "fcsr"}};
static constexpr std::array<const char*, 66> reg_aliases{
{"zero", "ra", "sp", "gp", "tp", "t0", "t1", "t2", "s0", "s1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "t3", "t4", "t5", "t6", "pc", "f0", "f1", "f2", "f3", "f4", "f5", "f6", "f7", "f8", "f9", "f10", "f11", "f12", "f13", "f14", "f15", "f16", "f17", "f18", "f19", "f20", "f21", "f22", "f23", "f24", "f25", "f26", "f27", "f28", "f29", "f30", "f31", "fcsr"}};
enum constants {XLEN=32, FLEN=64, PCLEN=32, MISA_VAL=0b1000000000101000001000100101101, PGSIZE=0x1000, PGMASK=0xfff};
constexpr static unsigned FP_REGS_SIZE = 64;
enum reg_e {
X0,
X1,
X2,
X3,
X4,
X5,
X6,
X7,
X8,
X9,
X10,
X11,
X12,
X13,
X14,
X15,
X16,
X17,
X18,
X19,
X20,
X21,
X22,
X23,
X24,
X25,
X26,
X27,
X28,
X29,
X30,
X31,
PC,
F0,
F1,
F2,
F3,
F4,
F5,
F6,
F7,
F8,
F9,
F10,
F11,
F12,
F13,
F14,
F15,
F16,
F17,
F18,
F19,
F20,
F21,
F22,
F23,
F24,
F25,
F26,
F27,
F28,
F29,
F30,
F31,
FCSR,
NUM_REGS,
NEXT_PC=NUM_REGS,
TRAP_STATE,
PENDING_TRAP,
MACHINE_STATE,
LAST_BRANCH,
ICOUNT,
ZERO = X0,
RA = X1,
SP = X2,
GP = X3,
TP = X4,
T0 = X5,
T1 = X6,
T2 = X7,
S0 = X8,
S1 = X9,
A0 = X10,
A1 = X11,
A2 = X12,
A3 = X13,
A4 = X14,
A5 = X15,
A6 = X16,
A7 = X17,
S2 = X18,
S3 = X19,
S4 = X20,
S5 = X21,
S6 = X22,
S7 = X23,
S8 = X24,
S9 = X25,
S10 = X26,
S11 = X27,
T3 = X28,
T4 = X29,
T5 = X30,
T6 = X31
};
using reg_t = uint32_t;
using addr_t = uint32_t;
using code_word_t = uint32_t; //TODO: check removal
using virt_addr_t = iss::typed_addr_t<iss::address_type::VIRTUAL>;
using phys_addr_t = iss::typed_addr_t<iss::address_type::PHYSICAL>;
static constexpr std::array<const uint32_t, 72> reg_bit_widths{
{32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,32,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,32,32,32,32,32,32,64}};
static constexpr std::array<const uint32_t, 73> reg_byte_offsets{
{0,4,8,12,16,20,24,28,32,36,40,44,48,52,56,60,64,68,72,76,80,84,88,92,96,100,104,108,112,116,120,124,128,136,144,152,160,168,176,184,192,200,208,216,224,232,240,248,256,264,272,280,288,296,304,312,320,328,336,344,352,360,368,376,384,392,396,400,404,408,412,416,424}};
static const uint64_t addr_mask = (reg_t(1) << (XLEN - 1)) | ((reg_t(1) << (XLEN - 1)) - 1);
enum sreg_flag_e { FLAGS };
enum mem_type_e { MEM, CSR, FENCE, RES };
};
struct rv32gc: public arch_if {
using virt_addr_t = typename traits<rv32gc>::virt_addr_t;
using phys_addr_t = typename traits<rv32gc>::phys_addr_t;
using reg_t = typename traits<rv32gc>::reg_t;
using addr_t = typename traits<rv32gc>::addr_t;
rv32gc();
~rv32gc();
void reset(uint64_t address=0) override;
uint8_t* get_regs_base_ptr() override;
/// deprecated
void get_reg(short idx, std::vector<uint8_t>& value) override {}
void set_reg(short idx, const std::vector<uint8_t>& value) override {}
/// deprecated
bool get_flag(int flag) override {return false;}
void set_flag(int, bool value) override {};
/// deprecated
void update_flags(operations op, uint64_t opr1, uint64_t opr2) override {};
inline uint64_t get_icount() { return reg.icount; }
inline bool should_stop() { return interrupt_sim; }
inline phys_addr_t v2p(const iss::addr_t& addr){
if (addr.space != traits<rv32gc>::MEM || addr.type == iss::address_type::PHYSICAL ||
addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) {
return phys_addr_t(addr.access, addr.space, addr.val&traits<rv32gc>::addr_mask);
} else
return virt2phys(addr);
}
virtual phys_addr_t virt2phys(const iss::addr_t& addr);
virtual iss::sync_type needed_sync() const { return iss::NO_SYNC; }
inline uint32_t get_last_branch() { return reg.last_branch; }
protected:
struct RV32GC_regs {
uint32_t X0 = 0;
uint32_t X1 = 0;
uint32_t X2 = 0;
uint32_t X3 = 0;
uint32_t X4 = 0;
uint32_t X5 = 0;
uint32_t X6 = 0;
uint32_t X7 = 0;
uint32_t X8 = 0;
uint32_t X9 = 0;
uint32_t X10 = 0;
uint32_t X11 = 0;
uint32_t X12 = 0;
uint32_t X13 = 0;
uint32_t X14 = 0;
uint32_t X15 = 0;
uint32_t X16 = 0;
uint32_t X17 = 0;
uint32_t X18 = 0;
uint32_t X19 = 0;
uint32_t X20 = 0;
uint32_t X21 = 0;
uint32_t X22 = 0;
uint32_t X23 = 0;
uint32_t X24 = 0;
uint32_t X25 = 0;
uint32_t X26 = 0;
uint32_t X27 = 0;
uint32_t X28 = 0;
uint32_t X29 = 0;
uint32_t X30 = 0;
uint32_t X31 = 0;
uint32_t PC = 0;
uint64_t F0 = 0;
uint64_t F1 = 0;
uint64_t F2 = 0;
uint64_t F3 = 0;
uint64_t F4 = 0;
uint64_t F5 = 0;
uint64_t F6 = 0;
uint64_t F7 = 0;
uint64_t F8 = 0;
uint64_t F9 = 0;
uint64_t F10 = 0;
uint64_t F11 = 0;
uint64_t F12 = 0;
uint64_t F13 = 0;
uint64_t F14 = 0;
uint64_t F15 = 0;
uint64_t F16 = 0;
uint64_t F17 = 0;
uint64_t F18 = 0;
uint64_t F19 = 0;
uint64_t F20 = 0;
uint64_t F21 = 0;
uint64_t F22 = 0;
uint64_t F23 = 0;
uint64_t F24 = 0;
uint64_t F25 = 0;
uint64_t F26 = 0;
uint64_t F27 = 0;
uint64_t F28 = 0;
uint64_t F29 = 0;
uint64_t F30 = 0;
uint64_t F31 = 0;
uint32_t FCSR = 0;
uint32_t NEXT_PC = 0;
uint32_t trap_state = 0, pending_trap = 0, machine_state = 0, last_branch = 0;
uint64_t icount = 0;
} reg;
std::array<address_type, 4> addr_mode;
bool interrupt_sim=false;
uint32_t get_fcsr(){return reg.FCSR;}
void set_fcsr(uint32_t val){reg.FCSR = val;}
};
}
}
#endif /* _RV32GC_H_ */

316
incl/iss/arch/rv64gc.h
View File

@@ -1,316 +0,0 @@
/*******************************************************************************
* Copyright (C) 2017, 2018 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*******************************************************************************/
#ifndef _RV64GC_H_
#define _RV64GC_H_
#include <array>
#include <iss/arch/traits.h>
#include <iss/arch_if.h>
#include <iss/vm_if.h>
namespace iss {
namespace arch {
struct rv64gc;
template <> struct traits<rv64gc> {
constexpr static char const* const core_type = "RV64GC";
static constexpr std::array<const char*, 66> reg_names{
{"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7", "x8", "x9", "x10", "x11", "x12", "x13", "x14", "x15", "x16", "x17", "x18", "x19", "x20", "x21", "x22", "x23", "x24", "x25", "x26", "x27", "x28", "x29", "x30", "x31", "pc", "f0", "f1", "f2", "f3", "f4", "f5", "f6", "f7", "f8", "f9", "f10", "f11", "f12", "f13", "f14", "f15", "f16", "f17", "f18", "f19", "f20", "f21", "f22", "f23", "f24", "f25", "f26", "f27", "f28", "f29", "f30", "f31", "fcsr"}};
static constexpr std::array<const char*, 66> reg_aliases{
{"zero", "ra", "sp", "gp", "tp", "t0", "t1", "t2", "s0", "s1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "t3", "t4", "t5", "t6", "pc", "f0", "f1", "f2", "f3", "f4", "f5", "f6", "f7", "f8", "f9", "f10", "f11", "f12", "f13", "f14", "f15", "f16", "f17", "f18", "f19", "f20", "f21", "f22", "f23", "f24", "f25", "f26", "f27", "f28", "f29", "f30", "f31", "fcsr"}};
enum constants {XLEN=64, FLEN=64, PCLEN=64, MISA_VAL=0b1000000000101000001000100101101, PGSIZE=0x1000, PGMASK=0xfff};
constexpr static unsigned FP_REGS_SIZE = 64;
enum reg_e {
X0,
X1,
X2,
X3,
X4,
X5,
X6,
X7,
X8,
X9,
X10,
X11,
X12,
X13,
X14,
X15,
X16,
X17,
X18,
X19,
X20,
X21,
X22,
X23,
X24,
X25,
X26,
X27,
X28,
X29,
X30,
X31,
PC,
F0,
F1,
F2,
F3,
F4,
F5,
F6,
F7,
F8,
F9,
F10,
F11,
F12,
F13,
F14,
F15,
F16,
F17,
F18,
F19,
F20,
F21,
F22,
F23,
F24,
F25,
F26,
F27,
F28,
F29,
F30,
F31,
FCSR,
NUM_REGS,
NEXT_PC=NUM_REGS,
TRAP_STATE,
PENDING_TRAP,
MACHINE_STATE,
LAST_BRANCH,
ICOUNT,
ZERO = X0,
RA = X1,
SP = X2,
GP = X3,
TP = X4,
T0 = X5,
T1 = X6,
T2 = X7,
S0 = X8,
S1 = X9,
A0 = X10,
A1 = X11,
A2 = X12,
A3 = X13,
A4 = X14,
A5 = X15,
A6 = X16,
A7 = X17,
S2 = X18,
S3 = X19,
S4 = X20,
S5 = X21,
S6 = X22,
S7 = X23,
S8 = X24,
S9 = X25,
S10 = X26,
S11 = X27,
T3 = X28,
T4 = X29,
T5 = X30,
T6 = X31
};
using reg_t = uint64_t;
using addr_t = uint64_t;
using code_word_t = uint64_t; //TODO: check removal
using virt_addr_t = iss::typed_addr_t<iss::address_type::VIRTUAL>;
using phys_addr_t = iss::typed_addr_t<iss::address_type::PHYSICAL>;
static constexpr std::array<const uint32_t, 72> reg_bit_widths{
{64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,32,64,32,32,32,32,64}};
static constexpr std::array<const uint32_t, 73> reg_byte_offsets{
{0,8,16,24,32,40,48,56,64,72,80,88,96,104,112,120,128,136,144,152,160,168,176,184,192,200,208,216,224,232,240,248,256,264,272,280,288,296,304,312,320,328,336,344,352,360,368,376,384,392,400,408,416,424,432,440,448,456,464,472,480,488,496,504,512,520,528,536,540,544,548,552,560}};
static const uint64_t addr_mask = (reg_t(1) << (XLEN - 1)) | ((reg_t(1) << (XLEN - 1)) - 1);
enum sreg_flag_e { FLAGS };
enum mem_type_e { MEM, CSR, FENCE, RES };
};
struct rv64gc: public arch_if {
using virt_addr_t = typename traits<rv64gc>::virt_addr_t;
using phys_addr_t = typename traits<rv64gc>::phys_addr_t;
using reg_t = typename traits<rv64gc>::reg_t;
using addr_t = typename traits<rv64gc>::addr_t;
rv64gc();
~rv64gc();
void reset(uint64_t address=0) override;
uint8_t* get_regs_base_ptr() override;
/// deprecated
void get_reg(short idx, std::vector<uint8_t>& value) override {}
void set_reg(short idx, const std::vector<uint8_t>& value) override {}
/// deprecated
bool get_flag(int flag) override {return false;}
void set_flag(int, bool value) override {};
/// deprecated
void update_flags(operations op, uint64_t opr1, uint64_t opr2) override {};
inline uint64_t get_icount() { return reg.icount; }
inline bool should_stop() { return interrupt_sim; }
inline phys_addr_t v2p(const iss::addr_t& addr){
if (addr.space != traits<rv64gc>::MEM || addr.type == iss::address_type::PHYSICAL ||
addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) {
return phys_addr_t(addr.access, addr.space, addr.val&traits<rv64gc>::addr_mask);
} else
return virt2phys(addr);
}
virtual phys_addr_t virt2phys(const iss::addr_t& addr);
virtual iss::sync_type needed_sync() const { return iss::NO_SYNC; }
inline uint32_t get_last_branch() { return reg.last_branch; }
protected:
struct RV64GC_regs {
uint64_t X0 = 0;
uint64_t X1 = 0;
uint64_t X2 = 0;
uint64_t X3 = 0;
uint64_t X4 = 0;
uint64_t X5 = 0;
uint64_t X6 = 0;
uint64_t X7 = 0;
uint64_t X8 = 0;
uint64_t X9 = 0;
uint64_t X10 = 0;
uint64_t X11 = 0;
uint64_t X12 = 0;
uint64_t X13 = 0;
uint64_t X14 = 0;
uint64_t X15 = 0;
uint64_t X16 = 0;
uint64_t X17 = 0;
uint64_t X18 = 0;
uint64_t X19 = 0;
uint64_t X20 = 0;
uint64_t X21 = 0;
uint64_t X22 = 0;
uint64_t X23 = 0;
uint64_t X24 = 0;
uint64_t X25 = 0;
uint64_t X26 = 0;
uint64_t X27 = 0;
uint64_t X28 = 0;
uint64_t X29 = 0;
uint64_t X30 = 0;
uint64_t X31 = 0;
uint64_t PC = 0;
uint64_t F0 = 0;
uint64_t F1 = 0;
uint64_t F2 = 0;
uint64_t F3 = 0;
uint64_t F4 = 0;
uint64_t F5 = 0;
uint64_t F6 = 0;
uint64_t F7 = 0;
uint64_t F8 = 0;
uint64_t F9 = 0;
uint64_t F10 = 0;
uint64_t F11 = 0;
uint64_t F12 = 0;
uint64_t F13 = 0;
uint64_t F14 = 0;
uint64_t F15 = 0;
uint64_t F16 = 0;
uint64_t F17 = 0;
uint64_t F18 = 0;
uint64_t F19 = 0;
uint64_t F20 = 0;
uint64_t F21 = 0;
uint64_t F22 = 0;
uint64_t F23 = 0;
uint64_t F24 = 0;
uint64_t F25 = 0;
uint64_t F26 = 0;
uint64_t F27 = 0;
uint64_t F28 = 0;
uint64_t F29 = 0;
uint64_t F30 = 0;
uint64_t F31 = 0;
uint32_t FCSR = 0;
uint64_t NEXT_PC = 0;
uint32_t trap_state = 0, pending_trap = 0, machine_state = 0, last_branch = 0;
uint64_t icount = 0;
} reg;
std::array<address_type, 4> addr_mode;
bool interrupt_sim=false;
uint32_t get_fcsr(){return reg.FCSR;}
void set_fcsr(uint32_t val){reg.FCSR = val;}
};
}
}
#endif /* _RV64GC_H_ */

250
incl/iss/arch/rv64i.h
View File

@@ -1,250 +0,0 @@
/*******************************************************************************
* Copyright (C) 2017, 2018 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*******************************************************************************/
#ifndef _RV64I_H_
#define _RV64I_H_
#include <array>
#include <iss/arch/traits.h>
#include <iss/arch_if.h>
#include <iss/vm_if.h>
namespace iss {
namespace arch {
struct rv64i;
template <> struct traits<rv64i> {
constexpr static char const* const core_type = "RV64I";
static constexpr std::array<const char*, 33> reg_names{
{"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7", "x8", "x9", "x10", "x11", "x12", "x13", "x14", "x15", "x16", "x17", "x18", "x19", "x20", "x21", "x22", "x23", "x24", "x25", "x26", "x27", "x28", "x29", "x30", "x31", "pc"}};
static constexpr std::array<const char*, 33> reg_aliases{
{"zero", "ra", "sp", "gp", "tp", "t0", "t1", "t2", "s0", "s1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "t3", "t4", "t5", "t6", "pc"}};
enum constants {XLEN=64, PCLEN=64, MISA_VAL=0b10000000000001000000000100000000, PGSIZE=0x1000, PGMASK=0xfff};
constexpr static unsigned FP_REGS_SIZE = 0;
enum reg_e {
X0,
X1,
X2,
X3,
X4,
X5,
X6,
X7,
X8,
X9,
X10,
X11,
X12,
X13,
X14,
X15,
X16,
X17,
X18,
X19,
X20,
X21,
X22,
X23,
X24,
X25,
X26,
X27,
X28,
X29,
X30,
X31,
PC,
NUM_REGS,
NEXT_PC=NUM_REGS,
TRAP_STATE,
PENDING_TRAP,
MACHINE_STATE,
LAST_BRANCH,
ICOUNT,
ZERO = X0,
RA = X1,
SP = X2,
GP = X3,
TP = X4,
T0 = X5,
T1 = X6,
T2 = X7,
S0 = X8,
S1 = X9,
A0 = X10,
A1 = X11,
A2 = X12,
A3 = X13,
A4 = X14,
A5 = X15,
A6 = X16,
A7 = X17,
S2 = X18,
S3 = X19,
S4 = X20,
S5 = X21,
S6 = X22,
S7 = X23,
S8 = X24,
S9 = X25,
S10 = X26,
S11 = X27,
T3 = X28,
T4 = X29,
T5 = X30,
T6 = X31
};
using reg_t = uint64_t;
using addr_t = uint64_t;
using code_word_t = uint64_t; //TODO: check removal
using virt_addr_t = iss::typed_addr_t<iss::address_type::VIRTUAL>;
using phys_addr_t = iss::typed_addr_t<iss::address_type::PHYSICAL>;
static constexpr std::array<const uint32_t, 39> reg_bit_widths{
{64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,64,32,32,32,32,64}};
static constexpr std::array<const uint32_t, 40> reg_byte_offsets{
{0,8,16,24,32,40,48,56,64,72,80,88,96,104,112,120,128,136,144,152,160,168,176,184,192,200,208,216,224,232,240,248,256,264,272,276,280,284,288,296}};
static const uint64_t addr_mask = (reg_t(1) << (XLEN - 1)) | ((reg_t(1) << (XLEN - 1)) - 1);
enum sreg_flag_e { FLAGS };
enum mem_type_e { MEM, CSR, FENCE, RES };
};
struct rv64i: public arch_if {
using virt_addr_t = typename traits<rv64i>::virt_addr_t;
using phys_addr_t = typename traits<rv64i>::phys_addr_t;
using reg_t = typename traits<rv64i>::reg_t;
using addr_t = typename traits<rv64i>::addr_t;
rv64i();
~rv64i();
void reset(uint64_t address=0) override;
uint8_t* get_regs_base_ptr() override;
/// deprecated
void get_reg(short idx, std::vector<uint8_t>& value) override {}
void set_reg(short idx, const std::vector<uint8_t>& value) override {}
/// deprecated
bool get_flag(int flag) override {return false;}
void set_flag(int, bool value) override {};
/// deprecated
void update_flags(operations op, uint64_t opr1, uint64_t opr2) override {};
inline uint64_t get_icount() { return reg.icount; }
inline bool should_stop() { return interrupt_sim; }
inline phys_addr_t v2p(const iss::addr_t& addr){
if (addr.space != traits<rv64i>::MEM || addr.type == iss::address_type::PHYSICAL ||
addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) {
return phys_addr_t(addr.access, addr.space, addr.val&traits<rv64i>::addr_mask);
} else
return virt2phys(addr);
}
virtual phys_addr_t virt2phys(const iss::addr_t& addr);
virtual iss::sync_type needed_sync() const { return iss::NO_SYNC; }
inline uint32_t get_last_branch() { return reg.last_branch; }
protected:
struct RV64I_regs {
uint64_t X0 = 0;
uint64_t X1 = 0;
uint64_t X2 = 0;
uint64_t X3 = 0;
uint64_t X4 = 0;
uint64_t X5 = 0;
uint64_t X6 = 0;
uint64_t X7 = 0;
uint64_t X8 = 0;
uint64_t X9 = 0;
uint64_t X10 = 0;
uint64_t X11 = 0;
uint64_t X12 = 0;
uint64_t X13 = 0;
uint64_t X14 = 0;
uint64_t X15 = 0;
uint64_t X16 = 0;
uint64_t X17 = 0;
uint64_t X18 = 0;
uint64_t X19 = 0;
uint64_t X20 = 0;
uint64_t X21 = 0;
uint64_t X22 = 0;
uint64_t X23 = 0;
uint64_t X24 = 0;
uint64_t X25 = 0;
uint64_t X26 = 0;
uint64_t X27 = 0;
uint64_t X28 = 0;
uint64_t X29 = 0;
uint64_t X30 = 0;
uint64_t X31 = 0;
uint64_t PC = 0;
uint64_t NEXT_PC = 0;
uint32_t trap_state = 0, pending_trap = 0, machine_state = 0, last_branch = 0;
uint64_t icount = 0;
} reg;
std::array<address_type, 4> addr_mode;
bool interrupt_sim=false;
uint32_t get_fcsr(){return 0;}
void set_fcsr(uint32_t val){}
};
}
}
#endif /* _RV64I_H_ */

34
incl/iss/arch/mnrv32.h → incl/iss/arch/tgf_b.h
View File

@@ -31,8 +31,8 @@
*******************************************************************************/ *******************************************************************************/
#ifndef _MNRV32_H_ #ifndef _TGF_B_H_
#define _MNRV32_H_ #define _TGF_B_H_
#include <array> #include <array>
#include <iss/arch/traits.h> #include <iss/arch/traits.h>
@@ -42,11 +42,11 @@
namespace iss { namespace iss {
namespace arch { namespace arch {
struct mnrv32; struct tgf_b;
template <> struct traits<mnrv32> { template <> struct traits<tgf_b> {
constexpr static char const* const core_type = "MNRV32"; constexpr static char const* const core_type = "TGF_B";
static constexpr std::array<const char*, 33> reg_names{ static constexpr std::array<const char*, 33> reg_names{
{"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7", "x8", "x9", "x10", "x11", "x12", "x13", "x14", "x15", "x16", "x17", "x18", "x19", "x20", "x21", "x22", "x23", "x24", "x25", "x26", "x27", "x28", "x29", "x30", "x31", "pc"}}; {"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7", "x8", "x9", "x10", "x11", "x12", "x13", "x14", "x15", "x16", "x17", "x18", "x19", "x20", "x21", "x22", "x23", "x24", "x25", "x26", "x27", "x28", "x29", "x30", "x31", "pc"}};
@@ -54,7 +54,7 @@ template <> struct traits<mnrv32> {
static constexpr std::array<const char*, 33> reg_aliases{ static constexpr std::array<const char*, 33> reg_aliases{
{"zero", "ra", "sp", "gp", "tp", "t0", "t1", "t2", "s0", "s1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "t3", "t4", "t5", "t6", "pc"}}; {"zero", "ra", "sp", "gp", "tp", "t0", "t1", "t2", "s0", "s1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "t3", "t4", "t5", "t6", "pc"}};
enum constants {XLEN=32, PCLEN=32, MISA_VAL=0b1000000000101000001000100000101, PGSIZE=0x1000, PGMASK=0xfff}; enum constants {XLEN=32, PCLEN=32, MISA_VAL=0b1000000000000000000000100000000, PGSIZE=0x1000, PGMASK=0xfff};
constexpr static unsigned FP_REGS_SIZE = 0; constexpr static unsigned FP_REGS_SIZE = 0;
@@ -156,15 +156,15 @@ template <> struct traits<mnrv32> {
enum mem_type_e { MEM, CSR, FENCE, RES }; enum mem_type_e { MEM, CSR, FENCE, RES };
}; };
struct mnrv32: public arch_if { struct tgf_b: public arch_if {
using virt_addr_t = typename traits<mnrv32>::virt_addr_t; using virt_addr_t = typename traits<tgf_b>::virt_addr_t;
using phys_addr_t = typename traits<mnrv32>::phys_addr_t; using phys_addr_t = typename traits<tgf_b>::phys_addr_t;
using reg_t = typename traits<mnrv32>::reg_t; using reg_t = typename traits<tgf_b>::reg_t;
using addr_t = typename traits<mnrv32>::addr_t; using addr_t = typename traits<tgf_b>::addr_t;
mnrv32(); tgf_b();
~mnrv32(); ~tgf_b();
void reset(uint64_t address=0) override; void reset(uint64_t address=0) override;
@@ -185,9 +185,9 @@ struct mnrv32: public arch_if {
inline uint64_t stop_code() { return interrupt_sim; } inline uint64_t stop_code() { return interrupt_sim; }
inline phys_addr_t v2p(const iss::addr_t& addr){ inline phys_addr_t v2p(const iss::addr_t& addr){
if (addr.space != traits<mnrv32>::MEM || addr.type == iss::address_type::PHYSICAL || if (addr.space != traits<tgf_b>::MEM || addr.type == iss::address_type::PHYSICAL ||
addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) { addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) {
return phys_addr_t(addr.access, addr.space, addr.val&traits<mnrv32>::addr_mask); return phys_addr_t(addr.access, addr.space, addr.val&traits<tgf_b>::addr_mask);
} else } else
return virt2phys(addr); return virt2phys(addr);
} }
@@ -199,7 +199,7 @@ struct mnrv32: public arch_if {
inline uint32_t get_last_branch() { return reg.last_branch; } inline uint32_t get_last_branch() { return reg.last_branch; }
protected: protected:
struct MNRV32_regs { struct TGF_B_regs {
uint32_t X0 = 0; uint32_t X0 = 0;
uint32_t X1 = 0; uint32_t X1 = 0;
uint32_t X2 = 0; uint32_t X2 = 0;
@@ -249,4 +249,4 @@ protected:
} }
} }
#endif /* _MNRV32_H_ */ #endif /* _TGF_B_H_ */

38
incl/iss/arch/rv32imac.h → incl/iss/arch/tgf_c.h
View File

@@ -31,8 +31,8 @@
*******************************************************************************/ *******************************************************************************/
#ifndef _RV32IMAC_H_ #ifndef _TGF_C_H_
#define _RV32IMAC_H_ #define _TGF_C_H_
#include <array> #include <array>
#include <iss/arch/traits.h> #include <iss/arch/traits.h>
@@ -42,11 +42,11 @@
namespace iss { namespace iss {
namespace arch { namespace arch {
struct rv32imac; struct tgf_c;
template <> struct traits<rv32imac> { template <> struct traits<tgf_c> {
constexpr static char const* const core_type = "RV32IMAC"; constexpr static char const* const core_type = "TGF_C";
static constexpr std::array<const char*, 33> reg_names{ static constexpr std::array<const char*, 33> reg_names{
{"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7", "x8", "x9", "x10", "x11", "x12", "x13", "x14", "x15", "x16", "x17", "x18", "x19", "x20", "x21", "x22", "x23", "x24", "x25", "x26", "x27", "x28", "x29", "x30", "x31", "pc"}}; {"x0", "x1", "x2", "x3", "x4", "x5", "x6", "x7", "x8", "x9", "x10", "x11", "x12", "x13", "x14", "x15", "x16", "x17", "x18", "x19", "x20", "x21", "x22", "x23", "x24", "x25", "x26", "x27", "x28", "x29", "x30", "x31", "pc"}};
@@ -54,7 +54,7 @@ template <> struct traits<rv32imac> {
static constexpr std::array<const char*, 33> reg_aliases{ static constexpr std::array<const char*, 33> reg_aliases{
{"zero", "ra", "sp", "gp", "tp", "t0", "t1", "t2", "s0", "s1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "t3", "t4", "t5", "t6", "pc"}}; {"zero", "ra", "sp", "gp", "tp", "t0", "t1", "t2", "s0", "s1", "a0", "a1", "a2", "a3", "a4", "a5", "a6", "a7", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "t3", "t4", "t5", "t6", "pc"}};
enum constants {XLEN=32, PCLEN=32, MISA_VAL=0b1000000000101000001000100000101, PGSIZE=0x1000, PGMASK=0xfff}; enum constants {XLEN=32, PCLEN=32, MUL_LEN=64, MISA_VAL=0b1000000000000000001000100000100, PGSIZE=0x1000, PGMASK=0xfff};
constexpr static unsigned FP_REGS_SIZE = 0; constexpr static unsigned FP_REGS_SIZE = 0;
@@ -156,15 +156,15 @@ template <> struct traits<rv32imac> {
enum mem_type_e { MEM, CSR, FENCE, RES }; enum mem_type_e { MEM, CSR, FENCE, RES };
}; };
struct rv32imac: public arch_if { struct tgf_c: public arch_if {
using virt_addr_t = typename traits<rv32imac>::virt_addr_t; using virt_addr_t = typename traits<tgf_c>::virt_addr_t;
using phys_addr_t = typename traits<rv32imac>::phys_addr_t; using phys_addr_t = typename traits<tgf_c>::phys_addr_t;
using reg_t = typename traits<rv32imac>::reg_t; using reg_t = typename traits<tgf_c>::reg_t;
using addr_t = typename traits<rv32imac>::addr_t; using addr_t = typename traits<tgf_c>::addr_t;
rv32imac(); tgf_c();
~rv32imac(); ~tgf_c();
void reset(uint64_t address=0) override; void reset(uint64_t address=0) override;
@@ -182,10 +182,12 @@ struct rv32imac: public arch_if {
inline bool should_stop() { return interrupt_sim; } inline bool should_stop() { return interrupt_sim; }
inline uint64_t stop_code() { return interrupt_sim; }
inline phys_addr_t v2p(const iss::addr_t& addr){ inline phys_addr_t v2p(const iss::addr_t& addr){
if (addr.space != traits<rv32imac>::MEM || addr.type == iss::address_type::PHYSICAL || if (addr.space != traits<tgf_c>::MEM || addr.type == iss::address_type::PHYSICAL ||
addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) { addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) {
return phys_addr_t(addr.access, addr.space, addr.val&traits<rv32imac>::addr_mask); return phys_addr_t(addr.access, addr.space, addr.val&traits<tgf_c>::addr_mask);
} else } else
return virt2phys(addr); return virt2phys(addr);
} }
@@ -197,7 +199,7 @@ struct rv32imac: public arch_if {
inline uint32_t get_last_branch() { return reg.last_branch; } inline uint32_t get_last_branch() { return reg.last_branch; }
protected: protected:
struct RV32IMAC_regs { struct TGF_C_regs {
uint32_t X0 = 0; uint32_t X0 = 0;
uint32_t X1 = 0; uint32_t X1 = 0;
uint32_t X2 = 0; uint32_t X2 = 0;
@@ -238,7 +240,7 @@ protected:
std::array<address_type, 4> addr_mode; std::array<address_type, 4> addr_mode;
bool interrupt_sim=false; uint64_t interrupt_sim=0;
uint32_t get_fcsr(){return 0;} uint32_t get_fcsr(){return 0;}
void set_fcsr(uint32_t val){} void set_fcsr(uint32_t val){}
@@ -247,4 +249,4 @@ protected:
} }
} }
#endif /* _RV32IMAC_H_ */ #endif /* _TGF_C_H_ */

29
incl/iss/debugger/riscv_target_adapter.h
View File

@@ -184,33 +184,28 @@ status riscv_target_adapter<ARCH>::read_registers(std::vector<uint8_t> &data, st
avail.clear(); avail.clear();
const uint8_t *reg_base = core->get_regs_base_ptr(); const uint8_t *reg_base = core->get_regs_base_ptr();
for (size_t reg_no = 0; reg_no < arch::traits<ARCH>::NUM_REGS; ++reg_no) { for (size_t reg_no = 0; reg_no < arch::traits<ARCH>::NUM_REGS; ++reg_no) {
auto reg_width = arch::traits<ARCH>::reg_bit_widths[static_cast<typename arch::traits<ARCH>::reg_e>(reg_no)] / 8; auto reg_width = arch::traits<ARCH>::reg_bit_widths[reg_no] / 8;
unsigned offset = traits<ARCH>::reg_byte_offsets[reg_no]; unsigned offset = traits<ARCH>::reg_byte_offsets[reg_no];
for (size_t j = 0; j < reg_width; ++j) { for (size_t j = 0; j < reg_width; ++j) {
data.push_back(*(reg_base + offset + j)); data.push_back(*(reg_base + offset + j));
avail.push_back(0xff); avail.push_back(0xff);
} }
// if(arch::traits<ARCH>::XLEN < 64)
// for(unsigned j=0; j<4; ++j){
// data.push_back(0);
// avail.push_back(0xff);
// }
} }
// work around fill with F type registers // work around fill with F type registers
if (arch::traits<ARCH>::NUM_REGS < 65) { // if (arch::traits<ARCH>::NUM_REGS < 65) {
auto reg_width = sizeof(typename arch::traits<ARCH>::reg_t); // auto reg_width = sizeof(typename arch::traits<ARCH>::reg_t);
for (size_t reg_no = 0; reg_no < 33; ++reg_no) { // for (size_t reg_no = 0; reg_no < 33; ++reg_no) {
for (size_t j = 0; j < reg_width; ++j) { // for (size_t j = 0; j < reg_width; ++j) {
data.push_back(0x0);
avail.push_back(0x00);
}
// if(arch::traits<ARCH>::XLEN < 64)
// for(unsigned j=0; j<4; ++j){
// data.push_back(0x0); // data.push_back(0x0);
// avail.push_back(0x00); // avail.push_back(0x00);
// } // }
} // // if(arch::traits<ARCH>::XLEN < 64)
} // // for(unsigned j=0; j<4; ++j){
// // data.push_back(0x0);
// // avail.push_back(0x00);
// // }
// }
// }
return Ok; return Ok;
} }

32
incl/sysc/core_complex.h
View File

@@ -51,12 +51,12 @@ template <class T_begin, class T_end> class scv_tr_generator;
namespace iss { namespace iss {
class vm_if; class vm_if;
namespace arch { namespace arch {
template <typename BASE> class riscv_hart_msu_vp; template <typename BASE> class riscv_hart_m_p;
} }
namespace debugger { namespace debugger {
class target_adapter_if; class target_adapter_if;
} }
} } // namespace iss
namespace sysc { namespace sysc {
@@ -75,31 +75,35 @@ class core_wrapper;
class core_complex : public sc_core::sc_module, public scc::traceable { class core_complex : public sc_core::sc_module, public scc::traceable {
public: public:
scc::initiator_mixin<scv4tlm::tlm_rec_initiator_socket<32>> initiator; scc::initiator_mixin<scv4tlm::tlm_rec_initiator_socket<32>> initiator{"intor"};
sc_core::sc_in<sc_core::sc_time> clk_i; sc_core::sc_in<sc_core::sc_time> clk_i{"clk_i"};
sc_core::sc_in<bool> rst_i; sc_core::sc_in<bool> rst_i{"rst_i"};
sc_core::sc_in<bool> global_irq_i; sc_core::sc_in<bool> global_irq_i{"global_irq_i"};
sc_core::sc_in<bool> timer_irq_i; sc_core::sc_in<bool> timer_irq_i{"timer_irq_i"};
sc_core::sc_in<bool> sw_irq_i; sc_core::sc_in<bool> sw_irq_i{"sw_irq_i"};
sc_core::sc_vector<sc_core::sc_in<bool>> local_irq_i; sc_core::sc_vector<sc_core::sc_in<bool>> local_irq_i{"local_irq_i", 16};
sc_core::sc_port<tlm::tlm_peek_if<uint64_t>, 1, sc_core::SC_ZERO_OR_MORE_BOUND> mtime_o; sc_core::sc_port<tlm::tlm_peek_if<uint64_t>, 1, sc_core::SC_ZERO_OR_MORE_BOUND> mtime_o;
cci::cci_param<std::string> elf_file; cci::cci_param<std::string> elf_file{"elf_file", ""};
cci::cci_param<bool> enable_disass; cci::cci_param<bool> enable_disass{"enable_disass", false};
cci::cci_param<uint64_t> reset_address; cci::cci_param<uint64_t> reset_address{"reset_address", 0ULL};
cci::cci_param<unsigned short> gdb_server_port; cci::cci_param<std::string> backend{"backend", "tcc"};
cci::cci_param<bool> dump_ir; cci::cci_param<unsigned short> gdb_server_port{"gdb_server_port", 0};
cci::cci_param<bool> dump_ir{"dump_ir", false};
cci::cci_param<uint32_t> mhartid{"mhartid", 0};
core_complex(sc_core::sc_module_name name); core_complex(sc_core::sc_module_name name);

59
softfloat/CMakeLists.txt
View File

@@ -2,31 +2,17 @@ cmake_minimum_required(VERSION 3.12)
set(CMAKE_MODULE_PATH ${CMAKE_MODULE_PATH} ${CMAKE_CURRENT_SOURCE_DIR}/../cmake) # main (top) cmake dir set(CMAKE_MODULE_PATH ${CMAKE_MODULE_PATH} ${CMAKE_CURRENT_SOURCE_DIR}/../cmake) # main (top) cmake dir
set(CMAKE_MODULE_PATH ${CMAKE_MODULE_PATH} ${CMAKE_CURRENT_SOURCE_DIR}/cmake) # project specific cmake dir set(CMAKE_MODULE_PATH ${CMAKE_MODULE_PATH} ${CMAKE_CURRENT_SOURCE_DIR}/cmake) # project specific cmake dir
# CMake useful variables
set(CMAKE_RUNTIME_OUTPUT_DIRECTORY "${CMAKE_BINARY_DIR}/bin")
set(CMAKE_ARCHIVE_OUTPUT_DIRECTORY "${CMAKE_BINARY_DIR}/lib")
set(CMAKE_LIBRARY_OUTPUT_DIRECTORY "${CMAKE_BINARY_DIR}/lib")
# Set the name of your project here # Set the name of your project here
project("sotfloat") project("sotfloat" VERSION 3.0.0)
# Set the version number of your project here (format is MAJOR.MINOR.PATCHLEVEL - e.g. 1.0.0) # Set the version number of your project here (format is MAJOR.MINOR.PATCHLEVEL - e.g. 1.0.0)
set(VERSION "3e") set(VERSION "3e")
include(Common) include(Common)
include(GNUInstallDirs)
set(SPECIALIZATION RISCV) set(SPECIALIZATION RISCV)
add_definitions(
-DSOFTFLOAT_ROUND_ODD
-DINLINE_LEVEL=5
-DSOFTFLOAT_FAST_DIV32TO16
-DSOFTFLOAT_FAST_DIV64TO32
-DSOFTFLOAT_FAST_INT64
# -DTHREAD_LOCAL=__thread
)
set(LIB_HEADERS source/include/softfloat.h source/include/softfloat_types.h) set(LIB_HEADERS source/include/softfloat.h source/include/softfloat_types.h)
set(PRIMITIVES set(PRIMITIVES
source/s_eq128.c source/s_eq128.c
@@ -341,32 +327,29 @@ set(OTHERS
set(LIB_SOURCES ${PRIMITIVES} ${SPECIALIZE} ${OTHERS}) set(LIB_SOURCES ${PRIMITIVES} ${SPECIALIZE} ${OTHERS})
# Define two variables in order not to repeat ourselves. add_library(softfloat ${LIB_SOURCES})
set(LIBRARY_NAME softfloat) set_property(TARGET softfloat PROPERTY C_STANDARD 99)
target_compile_definitions(softfloat PRIVATE
# Define the library SOFTFLOAT_ROUND_ODD
add_library(${LIBRARY_NAME} ${LIB_SOURCES}) INLINE_LEVEL=5
set_property(TARGET ${LIBRARY_NAME} PROPERTY C_STANDARD 99) SOFTFLOAT_FAST_DIV32TO16
target_include_directories(${LIBRARY_NAME} PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/build/Linux-x86_64-GCC) SOFTFLOAT_FAST_DIV64TO32
target_include_directories(${LIBRARY_NAME} PUBLIC ${CMAKE_CURRENT_SOURCE_DIR}/source/include ${CMAKE_CURRENT_SOURCE_DIR}/source/${SPECIALIZATION}) SOFTFLOAT_FAST_INT64
# Set the build version. It will be used in the name of the lib, with corresponding # THREAD_LOCAL=__thread
# symlinks created. SOVERSION could also be specified for api version. )
set_target_properties(${LIBRARY_NAME} PROPERTIES target_include_directories(softfloat PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/build/Linux-x86_64-GCC)
target_include_directories(softfloat PUBLIC ${CMAKE_CURRENT_SOURCE_DIR}/source/include ${CMAKE_CURRENT_SOURCE_DIR}/source/${SPECIALIZATION})
set_target_properties(softfloat PROPERTIES
VERSION ${VERSION} VERSION ${VERSION}
FRAMEWORK FALSE FRAMEWORK FALSE
PUBLIC_HEADER "${LIB_HEADERS}" PUBLIC_HEADER "${LIB_HEADERS}"
) )
# Says how and where to install software install(TARGETS softfloat
# Targets:
# * <prefix>/lib/<libraries>
# * header location after install: <prefix>/include/<project>/*.h
# * headers can be included by C++ code `#<project>/Bar.hpp>`
install(TARGETS ${LIBRARY_NAME}
EXPORT ${PROJECT_NAME}Targets # for downstream dependencies EXPORT ${PROJECT_NAME}Targets # for downstream dependencies
ARCHIVE DESTINATION lib COMPONENT libs # static lib ARCHIVE DESTINATION ${CMAKE_INSTALL_LIBDIR} COMPONENT libs # static lib
LIBRARY DESTINATION lib COMPONENT libs # shared lib LIBRARY DESTINATION ${CMAKE_INSTALL_LIBDIR} COMPONENT libs # shared lib
FRAMEWORK DESTINATION bin COMPONENT libs # for mac FRAMEWORK DESTINATION ${CMAKE_INSTALL_LIBDIR} COMPONENT libs # for mac
PUBLIC_HEADER DESTINATION include COMPONENT devel # headers for mac (note the different component -> different package) PUBLIC_HEADER DESTINATION ${CMAKE_INSTALL_INCLUDEDIR} COMPONENT devel # headers for mac (note the different component -> different package)
INCLUDES DESTINATION include # headers INCLUDES DESTINATION ${CMAKE_INSTALL_INCLUDEDIR} # headers
) )

80
src/iss/rv32gc.cpp
View File

@@ -1,80 +0,0 @@
/*******************************************************************************
* Copyright (C) 2017, 2018 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*******************************************************************************/
#include "util/ities.h"
#include <util/logging.h>
#include <elfio/elfio.hpp>
#include <iss/arch/rv32gc.h>
#ifdef __cplusplus
extern "C" {
#endif
#include <ihex.h>
#ifdef __cplusplus
}
#endif
#include <fstream>
#include <cstdio>
#include <cstring>
using namespace iss::arch;
constexpr std::array<const char*, 66> iss::arch::traits<iss::arch::rv32gc>::reg_names;
constexpr std::array<const char*, 66> iss::arch::traits<iss::arch::rv32gc>::reg_aliases;
constexpr std::array<const uint32_t, 72> iss::arch::traits<iss::arch::rv32gc>::reg_bit_widths;
constexpr std::array<const uint32_t, 73> iss::arch::traits<iss::arch::rv32gc>::reg_byte_offsets;
rv32gc::rv32gc() {
reg.icount=0;
}
rv32gc::~rv32gc(){
}
void rv32gc::reset(uint64_t address) {
for(size_t i=0; i<traits<rv32gc>::NUM_REGS; ++i) set_reg(i, std::vector<uint8_t>(sizeof(traits<rv32gc>::reg_t),0));
reg.PC=address;
reg.NEXT_PC=reg.PC;
reg.trap_state=0;
reg.machine_state=0x3;
reg.icount=0;
}
uint8_t* rv32gc::get_regs_base_ptr(){
return reinterpret_cast<uint8_t*>(&reg);
}
rv32gc::phys_addr_t rv32gc::virt2phys(const iss::addr_t &pc) {
return phys_addr_t(pc); // change logical address to physical address
}

77
src/iss/rv32imac.cpp
View File

@@ -1,77 +0,0 @@
/*******************************************************************************
* Copyright (C) 2017, 2018 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*******************************************************************************/
#include "util/ities.h"
#include <util/logging.h>
#include <elfio/elfio.hpp>
#include <iss/arch/rv32imac.h>
#ifdef __cplusplus
extern "C" {
#endif
#include <ihex.h>
#ifdef __cplusplus
}
#endif
#include <cstdio>
#include <cstring>
#include <fstream>
using namespace iss::arch;
constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::rv32imac>::reg_names;
constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::rv32imac>::reg_aliases;
constexpr std::array<const uint32_t, 39> iss::arch::traits<iss::arch::rv32imac>::reg_bit_widths;
constexpr std::array<const uint32_t, 40> iss::arch::traits<iss::arch::rv32imac>::reg_byte_offsets;
rv32imac::rv32imac() {
reg.icount = 0;
reg.machine_state = 0x3;
}
rv32imac::~rv32imac() = default;
void rv32imac::reset(uint64_t address) {
for (size_t i = 0; i < traits<rv32imac>::NUM_REGS; ++i)
set_reg(i, std::vector<uint8_t>(sizeof(traits<rv32imac>::reg_t), 0));
reg.PC = address;
reg.NEXT_PC = reg.PC;
reg.trap_state = 0;
reg.machine_state = 0x3;
}
uint8_t *rv32imac::get_regs_base_ptr() { return reinterpret_cast<uint8_t *>(&reg); }
rv32imac::phys_addr_t rv32imac::virt2phys(const iss::addr_t &pc) {
return phys_addr_t(pc); // change logical address to physical address
}

81
src/iss/rv64gc.cpp
View File

@@ -1,81 +0,0 @@
/*******************************************************************************
* Copyright (C) 2017, 2018 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*******************************************************************************/
#include "util/ities.h"
#include <util/logging.h>
#include <elfio/elfio.hpp>
#include <iss/arch/rv64gc.h>
#ifdef __cplusplus
extern "C" {
#endif
#include <ihex.h>
#ifdef __cplusplus
}
#endif
#include <cstdio>
#include <cstring>
#include <fstream>
using namespace iss::arch;
constexpr std::array<const char*, 66> iss::arch::traits<iss::arch::rv64gc>::reg_names;
constexpr std::array<const char*, 66> iss::arch::traits<iss::arch::rv64gc>::reg_aliases;
constexpr std::array<const uint32_t, 72> iss::arch::traits<iss::arch::rv64gc>::reg_bit_widths;
constexpr std::array<const uint32_t, 73> iss::arch::traits<iss::arch::rv64gc>::reg_byte_offsets;
rv64gc::rv64gc() {
reg.icount = 0;
}
rv64gc::~rv64gc() = default;
void rv64gc::reset(uint64_t address) {
for(size_t i=0; i<traits<rv64gc>::NUM_REGS; ++i) set_reg(i, std::vector<uint8_t>(sizeof(traits<rv64gc>::reg_t),0));
reg.PC=address;
reg.NEXT_PC=reg.PC;
reg.trap_state=0;
reg.machine_state=0x3;
reg.icount=0;
}
uint8_t *rv64gc::get_regs_base_ptr() {
return reinterpret_cast<uint8_t*>(&reg);
}
rv64gc::phys_addr_t rv64gc::virt2phys(const iss::addr_t &pc) {
return phys_addr_t(pc); // change logical address to physical address
}

32
src/iss/rv64i.cpp → src/iss/tgf_b.cpp
View File

@@ -32,36 +32,26 @@
#include "util/ities.h" #include "util/ities.h"
#include <util/logging.h> #include <util/logging.h>
#include <iss/arch/tgf_b.h>
#include <elfio/elfio.hpp>
#include <iss/arch/rv64i.h>
#ifdef __cplusplus
extern "C" {
#endif
#include <ihex.h>
#ifdef __cplusplus
}
#endif
#include <cstdio> #include <cstdio>
#include <cstring> #include <cstring>
#include <fstream> #include <fstream>
using namespace iss::arch; using namespace iss::arch;
constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::rv64i>::reg_names; constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::tgf_b>::reg_names;
constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::rv64i>::reg_aliases; constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::tgf_b>::reg_aliases;
constexpr std::array<const uint32_t, 39> iss::arch::traits<iss::arch::rv64i>::reg_bit_widths; constexpr std::array<const uint32_t, 39> iss::arch::traits<iss::arch::tgf_b>::reg_bit_widths;
constexpr std::array<const uint32_t, 40> iss::arch::traits<iss::arch::rv64i>::reg_byte_offsets; constexpr std::array<const uint32_t, 40> iss::arch::traits<iss::arch::tgf_b>::reg_byte_offsets;
rv64i::rv64i() { tgf_b::tgf_b() {
reg.icount = 0; reg.icount = 0;
} }
rv64i::~rv64i() = default; tgf_b::~tgf_b() = default;
void rv64i::reset(uint64_t address) { void tgf_b::reset(uint64_t address) {
for(size_t i=0; i<traits<rv64i>::NUM_REGS; ++i) set_reg(i, std::vector<uint8_t>(sizeof(traits<rv64i>::reg_t),0)); for(size_t i=0; i<traits<tgf_b>::NUM_REGS; ++i) set_reg(i, std::vector<uint8_t>(sizeof(traits<tgf_b>::reg_t),0));
reg.PC=address; reg.PC=address;
reg.NEXT_PC=reg.PC; reg.NEXT_PC=reg.PC;
reg.trap_state=0; reg.trap_state=0;
@@ -69,11 +59,11 @@ void rv64i::reset(uint64_t address) {
reg.icount=0; reg.icount=0;
} }
uint8_t *rv64i::get_regs_base_ptr() { uint8_t *tgf_b::get_regs_base_ptr() {
return reinterpret_cast<uint8_t*>(&reg); return reinterpret_cast<uint8_t*>(&reg);
} }
rv64i::phys_addr_t rv64i::virt2phys(const iss::addr_t &pc) { tgf_b::phys_addr_t tgf_b::virt2phys(const iss::addr_t &pc) {
return phys_addr_t(pc); // change logical address to physical address return phys_addr_t(pc); // change logical address to physical address
} }

32
src/iss/mnrv32.cpp → src/iss/tgf_c.cpp
View File

@@ -32,36 +32,26 @@
#include "util/ities.h" #include "util/ities.h"
#include <util/logging.h> #include <util/logging.h>
#include <iss/arch/tgf_c.h>
#include <elfio/elfio.hpp>
#include <iss/arch/mnrv32.h>
#ifdef __cplusplus
extern "C" {
#endif
#include <ihex.h>
#ifdef __cplusplus
}
#endif
#include <cstdio> #include <cstdio>
#include <cstring> #include <cstring>
#include <fstream> #include <fstream>
using namespace iss::arch; using namespace iss::arch;
constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::mnrv32>::reg_names; constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::tgf_c>::reg_names;
constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::mnrv32>::reg_aliases; constexpr std::array<const char*, 33> iss::arch::traits<iss::arch::tgf_c>::reg_aliases;
constexpr std::array<const uint32_t, 39> iss::arch::traits<iss::arch::mnrv32>::reg_bit_widths; constexpr std::array<const uint32_t, 39> iss::arch::traits<iss::arch::tgf_c>::reg_bit_widths;
constexpr std::array<const uint32_t, 40> iss::arch::traits<iss::arch::mnrv32>::reg_byte_offsets; constexpr std::array<const uint32_t, 40> iss::arch::traits<iss::arch::tgf_c>::reg_byte_offsets;
mnrv32::mnrv32() { tgf_c::tgf_c() {
reg.icount = 0; reg.icount = 0;
} }
mnrv32::~mnrv32() = default; tgf_c::~tgf_c() = default;
void mnrv32::reset(uint64_t address) { void tgf_c::reset(uint64_t address) {
for(size_t i=0; i<traits<mnrv32>::NUM_REGS; ++i) set_reg(i, std::vector<uint8_t>(sizeof(traits<mnrv32>::reg_t),0)); for(size_t i=0; i<traits<tgf_c>::NUM_REGS; ++i) set_reg(i, std::vector<uint8_t>(sizeof(traits<tgf_c>::reg_t),0));
reg.PC=address; reg.PC=address;
reg.NEXT_PC=reg.PC; reg.NEXT_PC=reg.PC;
reg.trap_state=0; reg.trap_state=0;
@@ -69,11 +59,11 @@ void mnrv32::reset(uint64_t address) {
reg.icount=0; reg.icount=0;
} }
uint8_t *mnrv32::get_regs_base_ptr() { uint8_t *tgf_c::get_regs_base_ptr() {
return reinterpret_cast<uint8_t*>(&reg); return reinterpret_cast<uint8_t*>(&reg);
} }
mnrv32::phys_addr_t mnrv32::virt2phys(const iss::addr_t &pc) { tgf_c::phys_addr_t tgf_c::virt2phys(const iss::addr_t &pc) {
return phys_addr_t(pc); // change logical address to physical address return phys_addr_t(pc); // change logical address to physical address
} }

56
src/main.cpp
View File

@@ -35,15 +35,35 @@
#include <boost/lexical_cast.hpp> #include <boost/lexical_cast.hpp>
#include <boost/program_options.hpp> #include <boost/program_options.hpp>
#include <iss/arch/riscv_hart_msu_vp.h> #include <iss/arch/riscv_hart_m_p.h>
#include <iss/arch/mnrv32.h> #include <iss/arch/tgf_b.h>
#include <iss/arch/tgf_c.h>
#ifdef WITH_LLVM
#include <iss/llvm/jit_helper.h> #include <iss/llvm/jit_helper.h>
#endif
#include <iss/log_categories.h> #include <iss/log_categories.h>
#include <iss/plugin/cycle_estimate.h> #include <iss/plugin/cycle_estimate.h>
#include <iss/plugin/instruction_count.h> #include <iss/plugin/instruction_count.h>
namespace po = boost::program_options; namespace po = boost::program_options;
using cpu_ptr = std::unique_ptr<iss::arch_if>;
using vm_ptr= std::unique_ptr<iss::vm_if>;
template<typename CORE>
std::tuple<cpu_ptr, vm_ptr> create_cpu(std::string const& backend, unsigned gdb_port){
CORE* lcpu = new iss::arch::riscv_hart_m_p<CORE>();
if(backend == "interp")
return {cpu_ptr{lcpu}, vm_ptr{iss::interp::create(lcpu, gdb_port)}};
#ifdef WITH_LLVM
if(backend == "llvm")
return {cpu_ptr{lcpu}, vm_ptr{iss::llvm::create(lcpu, gdb_port)}};
#endif
if(backend == "tcc")
return {cpu_ptr{lcpu}, vm_ptr{iss::tcc::create(lcpu, gdb_port)}};
return {nullptr, nullptr};
}
int main(int argc, char *argv[]) { int main(int argc, char *argv[]) {
/* /*
* Define and parse the program options * Define and parse the program options
@@ -64,7 +84,7 @@ int main(int argc, char *argv[]) {
("mem,m", po::value<std::string>(), "the memory input file") ("mem,m", po::value<std::string>(), "the memory input file")
("plugin,p", po::value<std::vector<std::string>>(), "plugin to activate") ("plugin,p", po::value<std::vector<std::string>>(), "plugin to activate")
("backend", po::value<std::string>()->default_value("tcc"), "the memory input file") ("backend", po::value<std::string>()->default_value("tcc"), "the memory input file")
("isa", po::value<std::string>()->default_value("rv32gc"), "isa to use for simulation"); ("isa", po::value<std::string>()->default_value("tgf_c"), "isa to use for simulation");
// clang-format on // clang-format on
auto parsed = po::command_line_parser(argc, argv).options(desc).allow_unregistered().run(); auto parsed = po::command_line_parser(argc, argv).options(desc).allow_unregistered().run();
try { try {
@@ -100,24 +120,28 @@ int main(int argc, char *argv[]) {
std::vector<iss::vm_plugin *> plugin_list; std::vector<iss::vm_plugin *> plugin_list;
auto res = 0; auto res = 0;
try { try {
#ifdef WITH_LLVM
// application code comes here // // application code comes here //
iss::init_jit_debug(argc, argv); iss::init_jit_debug(argc, argv);
#endif
bool dump = clim.count("dump-ir"); bool dump = clim.count("dump-ir");
// instantiate the simulator // instantiate the simulator
std::unique_ptr<iss::vm_if> vm{nullptr}; vm_ptr vm{nullptr};
std::unique_ptr<iss::arch_if> cpu{nullptr}; cpu_ptr cpu{nullptr};
std::string isa_opt(clim["isa"].as<std::string>()); std::string isa_opt(clim["isa"].as<std::string>());
iss::arch::mnrv32* lcpu = new iss::arch::riscv_hart_msu_vp<iss::arch::mnrv32>(); if (isa_opt == "tgf_b") {
if(clim["backend"].as<std::string>() == "interp") std::tie(cpu, vm) =
vm = iss::interp::create(lcpu, clim["gdb-port"].as<unsigned>()); create_cpu<iss::arch::tgf_b>(clim["backend"].as<std::string>(), clim["gdb-port"].as<unsigned>());
if(clim["backend"].as<std::string>() == "llvm") } else if (isa_opt == "tgf_c") {
vm = iss::llvm::create(lcpu, clim["gdb-port"].as<unsigned>()); std::tie(cpu, vm) =
if(clim["backend"].as<std::string>() == "tcc") create_cpu<iss::arch::tgf_c>(clim["backend"].as<std::string>(), clim["gdb-port"].as<unsigned>());
vm = iss::tcc::create(lcpu, clim["gdb-port"].as<unsigned>()); } else {
cpu.reset(lcpu); LOG(ERROR) << "Illegal argument value for '--isa': " << clim["isa"].as<std::string>() << std::endl;
return 127;
}
if (clim.count("plugin")) { if (clim.count("plugin")) {
for (std::string opt_val : clim["plugin"].as<std::vector<std::string>>()) { for (std::string const& opt_val : clim["plugin"].as<std::vector<std::string>>()) {
std::string plugin_name{opt_val}; std::string plugin_name=opt_val;
std::string filename{"cycles.txt"}; std::string filename{"cycles.txt"};
std::size_t found = opt_val.find('='); std::size_t found = opt_val.find('=');
if (found != std::string::npos) { if (found != std::string::npos) {
@@ -150,7 +174,7 @@ int main(int argc, char *argv[]) {
} }
uint64_t start_address = 0; uint64_t start_address = 0;
if (clim.count("mem")) if (clim.count("mem"))
vm->get_arch()->load_file(clim["mem"].as<std::string>(), iss::arch::traits<iss::arch::mnrv32>::MEM); vm->get_arch()->load_file(clim["mem"].as<std::string>(), iss::arch::traits<iss::arch::tgf_b>::MEM);
if (clim.count("elf")) if (clim.count("elf"))
for (std::string input : clim["elf"].as<std::vector<std::string>>()) { for (std::string input : clim["elf"].as<std::vector<std::string>>()) {
auto start_addr = vm->get_arch()->load_file(input); auto start_addr = vm->get_arch()->load_file(input);

55
src/sysc/core_complex.cpp
View File

@@ -31,9 +31,8 @@
*******************************************************************************/ *******************************************************************************/
#include "sysc/core_complex.h" #include "sysc/core_complex.h"
#include "iss/arch/riscv_hart_msu_vp.h" #include "iss/arch/riscv_hart_m_p.h"
//#include "iss/arch/rv32imac.h" #include "iss/arch/tgf_c.h"
#include "iss/arch/mnrv32.h"
#include "iss/debugger/encoderdecoder.h" #include "iss/debugger/encoderdecoder.h"
#include "iss/debugger/gdb_session.h" #include "iss/debugger/gdb_session.h"
#include "iss/debugger/server.h" #include "iss/debugger/server.h"
@@ -41,8 +40,8 @@
#include "iss/iss.h" #include "iss/iss.h"
#include "iss/vm_types.h" #include "iss/vm_types.h"
#include "scc/report.h" #include "scc/report.h"
#include <sstream>
#include <iostream> #include <iostream>
#include <sstream>
#ifdef WITH_SCV #ifdef WITH_SCV
#include <array> #include <array>
@@ -60,8 +59,7 @@ namespace {
iss::debugger::encoder_decoder encdec; iss::debugger::encoder_decoder encdec;
} }
//using core_type = iss::arch::rv32imac; using core_type = iss::arch::tgf_c;
using core_type = iss::arch::mnrv32;
namespace { namespace {
@@ -91,14 +89,12 @@ std::array<const char*, 12> irq_str = { {
"User external interrupt", "Supervisor external interrupt", "Reserved", "Machine external interrupt" } }; "User external interrupt", "Supervisor external interrupt", "Reserved", "Machine external interrupt" } };
} }
class core_wrapper : public iss::arch::riscv_hart_msu_vp<core_type> { class core_wrapper : public iss::arch::riscv_hart_m_p<core_type> {
public: public:
using base_type = arch::riscv_hart_msu_vp<core_type>; using base_type = arch::riscv_hart_m_p<core_type>;
using phys_addr_t = typename arch::traits<core_type>::phys_addr_t; using phys_addr_t = typename arch::traits<core_type>::phys_addr_t;
core_wrapper(core_complex *owner) core_wrapper(core_complex *owner)
: owner(owner) : owner(owner) { }
{
}
uint32_t get_mode() { return this->reg.machine_state; } uint32_t get_mode() { return this->reg.machine_state; }
@@ -166,7 +162,7 @@ public:
} }
void wait_until(uint64_t flags) override { void wait_until(uint64_t flags) override {
SCDEBUG(owner->name()) << "Sleeping until interrupt"; SCCDEBUG(owner->name()) << "Sleeping until interrupt";
do { do {
wait(wfi_evt); wait(wfi_evt);
} while (this->reg.pending_trap == 0); } while (this->reg.pending_trap == 0);
@@ -222,7 +218,7 @@ int cmd_sysc(int argc, char *argv[], debugger::out_func of, debugger::data_func
return Err; return Err;
// no check needed as it is only called if debug server is active // no check needed as it is only called if debug server is active
tgt_adapter->add_break_condition([t]() -> unsigned { tgt_adapter->add_break_condition([t]() -> unsigned {
SCTRACE() << "Checking condition at " << sc_time_stamp(); SCCTRACE() << "Checking condition at " << sc_time_stamp();
return sc_time_stamp() >= t ? std::numeric_limits<unsigned>::max() : 0; return sc_time_stamp() >= t ? std::numeric_limits<unsigned>::max() : 0;
}); });
return Ok; return Ok;
@@ -234,17 +230,6 @@ int cmd_sysc(int argc, char *argv[], debugger::out_func of, debugger::data_func
core_complex::core_complex(sc_module_name name) core_complex::core_complex(sc_module_name name)
: sc_module(name) : sc_module(name)
, NAMED(initiator)
, NAMED(clk_i)
, NAMED(rst_i)
, NAMED(global_irq_i)
, NAMED(timer_irq_i)
, NAMED(local_irq_i, 16)
, NAMED(elf_file, "")
, NAMED(enable_disass, false)
, NAMED(reset_address, 0ULL)
, NAMED(gdb_server_port, 0)
, NAMED(dump_ir, false)
, read_lut(tlm_dmi_ext()) , read_lut(tlm_dmi_ext())
, write_lut(tlm_dmi_ext()) , write_lut(tlm_dmi_ext())
, tgt_adapter(nullptr) , tgt_adapter(nullptr)
@@ -284,9 +269,25 @@ core_complex::~core_complex() = default;
void core_complex::trace(sc_trace_file *trf) const {} void core_complex::trace(sc_trace_file *trf) const {}
using vm_ptr= std::unique_ptr<iss::vm_if>;
vm_ptr create_cpu(core_wrapper* cpu, std::string const& backend, unsigned gdb_port){
if(backend == "interp")
return vm_ptr{iss::interp::create<core_type>(cpu, gdb_port)};
#ifdef WITH_LLVM
if(backend == "llvm")
return vm_ptr{iss::llvm::create(lcpu, gdb_port)};
#endif
if(backend == "tcc")
return vm_ptr{iss::tcc::create<core_type>(cpu, gdb_port)};
return {nullptr};
}
void core_complex::before_end_of_elaboration() { void core_complex::before_end_of_elaboration() {
SCCDEBUG(SCMOD)<<"instantiating iss::arch::tgf with "<<backend.get_value()<<" backend";
cpu = scc::make_unique<core_wrapper>(this); cpu = scc::make_unique<core_wrapper>(this);
vm = llvm::create<core_type>(cpu.get(), gdb_server_port.get_value(), dump_ir.get_value()); cpu->set_mhartid(mhartid.get_value());
vm = create_cpu(cpu.get(), backend.get_value(), gdb_server_port.get_value());
#ifdef WITH_SCV #ifdef WITH_SCV
vm->setDisassEnabled(enable_disass.get_value() || m_db != nullptr); vm->setDisassEnabled(enable_disass.get_value() || m_db != nullptr);
#else #else
@@ -392,7 +393,7 @@ bool core_complex::read_mem(uint64_t addr, unsigned length, uint8_t *const data,
} }
#endif #endif
initiator->b_transport(gp, delay); initiator->b_transport(gp, delay);
SCTRACE(this->name()) << "read_mem(0x" << std::hex << addr << ") : " << data; SCCTRACE(this->name()) << "read_mem(0x" << std::hex << addr << ") : " << data;
if (gp.get_response_status() != tlm::TLM_OK_RESPONSE) { if (gp.get_response_status() != tlm::TLM_OK_RESPONSE) {
return false; return false;
} }
@@ -439,7 +440,7 @@ bool core_complex::write_mem(uint64_t addr, unsigned length, const uint8_t *cons
#endif #endif
initiator->b_transport(gp, delay); initiator->b_transport(gp, delay);
quantum_keeper.set(delay); quantum_keeper.set(delay);
SCTRACE() << "write_mem(0x" << std::hex << addr << ") : " << data; SCCTRACE() << "write_mem(0x" << std::hex << addr << ") : " << data;
if (gp.get_response_status() != tlm::TLM_OK_RESPONSE) { if (gp.get_response_status() != tlm::TLM_OK_RESPONSE) {
return false; return false;
} }

68
src/vm/llvm/fp_functions.cpp → src/vm/fp_functions.cpp
View File

@@ -32,8 +32,7 @@
// eyck@minres.com - initial API and implementation // eyck@minres.com - initial API and implementation
//////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////////
#include <iss/iss.h> #include "fp_functions.h"
#include <iss/llvm/vm_base.h>
extern "C" { extern "C" {
#include <softfloat.h> #include <softfloat.h>
@@ -43,71 +42,6 @@ extern "C" {
#include <limits> #include <limits>
namespace iss {
namespace llvm {
namespace fp_impl {
using namespace std;
using namespace ::llvm;
#define INT_TYPE(L) Type::getIntNTy(mod->getContext(), L)
#define FLOAT_TYPE Type::getFloatTy(mod->getContext())
#define DOUBLE_TYPE Type::getDoubleTy(mod->getContext())
#define VOID_TYPE Type::getVoidTy(mod->getContext())
#define THIS_PTR_TYPE Type::getIntNPtrTy(mod->getContext(), 8)
#define FDECLL(NAME, RET, ...) \
Function *NAME##_func = CurrentModule->getFunction(#NAME); \
if (!NAME##_func) { \
std::vector<Type *> NAME##_args{__VA_ARGS__}; \
FunctionType *NAME##_type = FunctionType::get(RET, NAME##_args, false); \
NAME##_func = Function::Create(NAME##_type, GlobalValue::ExternalLinkage, #NAME, CurrentModule); \
NAME##_func->setCallingConv(CallingConv::C); \
}
#define FDECL(NAME, RET, ...) \
std::vector<Type *> NAME##_args{__VA_ARGS__}; \
FunctionType *NAME##_type = FunctionType::get(RET, NAME##_args, false); \
mod->getOrInsertFunction(#NAME, NAME##_type);
void add_fp_functions_2_module(Module *mod, uint32_t flen, uint32_t xlen) {
if(flen){
FDECL(fget_flags, INT_TYPE(32));
FDECL(fadd_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fsub_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fmul_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fdiv_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fsqrt_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fcmp_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(32));
FDECL(fcvt_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fmadd_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fsel_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(32));
FDECL(fclass_s, INT_TYPE(32), INT_TYPE(32));
FDECL(fcvt_32_64, INT_TYPE(64), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fcvt_64_32, INT_TYPE(32), INT_TYPE(64), INT_TYPE(32), INT_TYPE(8));
if(flen>32){
FDECL(fconv_d2f, INT_TYPE(32), INT_TYPE(64), INT_TYPE(8));
FDECL(fconv_f2d, INT_TYPE(64), INT_TYPE(32), INT_TYPE(8));
FDECL(fadd_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fsub_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fmul_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fdiv_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fsqrt_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fcmp_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(32));
FDECL(fcvt_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(32), INT_TYPE(8));
FDECL(fmadd_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(32), INT_TYPE(8));
FDECL(fsel_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(32));
FDECL(fclass_d, INT_TYPE(64), INT_TYPE(64));
FDECL(unbox_s, INT_TYPE(32), INT_TYPE(64));
}
}
}
}
}
}
using this_t = uint8_t *; using this_t = uint8_t *;
const uint8_t rmm_map[] = { const uint8_t rmm_map[] = {
softfloat_round_near_even /*RNE*/, softfloat_round_near_even /*RNE*/,

68
src/vm/fp_functions.h Normal file
View File

@@ -0,0 +1,68 @@
////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2020, MINRES Technologies GmbH
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are met:
//
// 1. Redistributions of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
//
// 2. Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
//
// 3. Neither the name of the copyright holder nor the names of its contributors
// may be used to endorse or promote products derived from this software
// without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
// Contributors:
// eyck@minres.com - initial API and implementation
////////////////////////////////////////////////////////////////////////////////
#ifndef _VM_FP_FUNCTIONS_H_
#define _VM_FP_FUNCTIONS_H_
#include <stdint.h>
extern "C" {
uint32_t fget_flags();
uint32_t fadd_s(uint32_t v1, uint32_t v2, uint8_t mode);
uint32_t fsub_s(uint32_t v1, uint32_t v2, uint8_t mode);
uint32_t fmul_s(uint32_t v1, uint32_t v2, uint8_t mode);
uint32_t fdiv_s(uint32_t v1, uint32_t v2, uint8_t mode);
uint32_t fsqrt_s(uint32_t v1, uint8_t mode);
uint32_t fcmp_s(uint32_t v1, uint32_t v2, uint32_t op) ;
uint32_t fcvt_s(uint32_t v1, uint32_t op, uint8_t mode);
uint32_t fmadd_s(uint32_t v1, uint32_t v2, uint32_t v3, uint32_t op, uint8_t mode);
uint32_t fsel_s(uint32_t v1, uint32_t v2, uint32_t op);
uint32_t fclass_s( uint32_t v1 );
uint32_t fconv_d2f(uint64_t v1, uint8_t mode);
uint64_t fconv_f2d(uint32_t v1, uint8_t mode);
uint64_t fadd_d(uint64_t v1, uint64_t v2, uint8_t mode);
uint64_t fsub_d(uint64_t v1, uint64_t v2, uint8_t mode);
uint64_t fmul_d(uint64_t v1, uint64_t v2, uint8_t mode);
uint64_t fdiv_d(uint64_t v1, uint64_t v2, uint8_t mode);
uint64_t fsqrt_d(uint64_t v1, uint8_t mode);
uint64_t fcmp_d(uint64_t v1, uint64_t v2, uint32_t op);
uint64_t fcvt_d(uint64_t v1, uint32_t op, uint8_t mode);
uint64_t fmadd_d(uint64_t v1, uint64_t v2, uint64_t v3, uint32_t op, uint8_t mode);
uint64_t fsel_d(uint64_t v1, uint64_t v2, uint32_t op) ;
uint64_t fclass_d(uint64_t v1 );
uint64_t fcvt_32_64(uint32_t v1, uint32_t op, uint8_t mode);
uint32_t fcvt_64_32(uint64_t v1, uint32_t op, uint8_t mode);
uint32_t unbox_s(uint64_t v);
}
#endif /* RISCV_SRC_VM_FP_FUNCTIONS_H_ */

2072
src/vm/interp/vm_tgf_b.cpp Normal file
View File

File diff suppressed because it is too large Load Diff

521
src/vm/interp/vm_mnrv32.cpp → src/vm/interp/vm_tgf_c.cpp
View File

@@ -30,8 +30,9 @@
* *
*******************************************************************************/ *******************************************************************************/
#include <iss/arch/mnrv32.h> #include "../fp_functions.h"
#include <iss/arch/riscv_hart_msu_vp.h> #include <iss/arch/tgf_c.h>
#include <iss/arch/riscv_hart_m_p.h>
#include <iss/debugger/gdb_session.h> #include <iss/debugger/gdb_session.h>
#include <iss/debugger/server.h> #include <iss/debugger/server.h>
#include <iss/iss.h> #include <iss/iss.h>
@@ -49,7 +50,7 @@
namespace iss { namespace iss {
namespace interp { namespace interp {
namespace mnrv32 { namespace tgf_c {
using namespace iss::arch; using namespace iss::arch;
using namespace iss::debugger; using namespace iss::debugger;
@@ -166,7 +167,7 @@ private:
compile_func op; compile_func op;
}; };
const std::array<InstructionDesriptor, 80> instr_descr = {{ const std::array<InstructionDesriptor, 88> instr_descr = {{
/* entries are: size, valid value, valid mask, function ptr */ /* entries are: size, valid value, valid mask, function ptr */
/* instruction LUI */ /* instruction LUI */
{32, 0b00000000000000000000000000110111, 0b00000000000000000000000001111111, &this_class::__lui}, {32, 0b00000000000000000000000000110111, 0b00000000000000000000000001111111, &this_class::__lui},
@@ -272,6 +273,22 @@ private:
{32, 0b00000000000000000110000001110011, 0b00000000000000000111000001111111, &this_class::__csrrsi}, {32, 0b00000000000000000110000001110011, 0b00000000000000000111000001111111, &this_class::__csrrsi},
/* instruction CSRRCI */ /* instruction CSRRCI */
{32, 0b00000000000000000111000001110011, 0b00000000000000000111000001111111, &this_class::__csrrci}, {32, 0b00000000000000000111000001110011, 0b00000000000000000111000001111111, &this_class::__csrrci},
/* instruction MUL */
{32, 0b00000010000000000000000000110011, 0b11111110000000000111000001111111, &this_class::__mul},
/* instruction MULH */
{32, 0b00000010000000000001000000110011, 0b11111110000000000111000001111111, &this_class::__mulh},
/* instruction MULHSU */
{32, 0b00000010000000000010000000110011, 0b11111110000000000111000001111111, &this_class::__mulhsu},
/* instruction MULHU */
{32, 0b00000010000000000011000000110011, 0b11111110000000000111000001111111, &this_class::__mulhu},
/* instruction DIV */
{32, 0b00000010000000000100000000110011, 0b11111110000000000111000001111111, &this_class::__div},
/* instruction DIVU */
{32, 0b00000010000000000101000000110011, 0b11111110000000000111000001111111, &this_class::__divu},
/* instruction REM */
{32, 0b00000010000000000110000000110011, 0b11111110000000000111000001111111, &this_class::__rem},
/* instruction REMU */
{32, 0b00000010000000000111000000110011, 0b11111110000000000111000001111111, &this_class::__remu},
/* instruction C.ADDI4SPN */ /* instruction C.ADDI4SPN */
{16, 0b0000000000000000, 0b1110000000000011, &this_class::__c_addi4spn}, {16, 0b0000000000000000, 0b1110000000000011, &this_class::__c_addi4spn},
/* instruction C.LW */ /* instruction C.LW */
@@ -2051,10 +2068,334 @@ private:
return pc; return pc;
} }
/* instruction 52: C.ADDI4SPN */ /* instruction 52: MUL */
compile_ret_t __c_addi4spn(virt_addr_t& pc, code_word_t instr){ compile_ret_t __mul(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 52); this->do_sync(PRE_SYNC, 52);
uint8_t rd = ((bit_sub<7,5>(instr)));
uint8_t rs1 = ((bit_sub<15,5>(instr)));
uint8_t rs2 = ((bit_sub<20,5>(instr)));
if(this->disass_enabled){
/* generate console output when executing the command */
auto mnemonic = fmt::format(
"{mnemonic:10} {rd}, {rs1}, {rs2}", fmt::arg("mnemonic", "mul"),
fmt::arg("rd", name(rd)), fmt::arg("rs1", name(rs1)), fmt::arg("rs2", name(rs2)));
this->core.disass_output(pc.val, mnemonic);
}
auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 4;
if(rd != 0){
auto res_val = (super::template zext<uint64_t>(super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)) * super::template zext<uint64_t>(super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0)));
auto Xtmp0_val = super::template zext<uint32_t>(res_val);
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
}
this->do_sync(POST_SYNC, 52);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check
if(trap_state!=0){
auto& last_br = super::template get_reg<uint32_t>(arch::traits<ARCH>::LAST_BRANCH);
last_br = std::numeric_limits<uint32_t>::max();
super::core.enter_trap(trap_state, cur_pc_val);
}
pc.val=super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC);
return pc;
}
/* instruction 53: MULH */
compile_ret_t __mulh(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 53);
uint8_t rd = ((bit_sub<7,5>(instr)));
uint8_t rs1 = ((bit_sub<15,5>(instr)));
uint8_t rs2 = ((bit_sub<20,5>(instr)));
if(this->disass_enabled){
/* generate console output when executing the command */
auto mnemonic = fmt::format(
"{mnemonic:10} {rd}, {rs1}, {rs2}", fmt::arg("mnemonic", "mulh"),
fmt::arg("rd", name(rd)), fmt::arg("rs1", name(rs1)), fmt::arg("rs2", name(rs2)));
this->core.disass_output(pc.val, mnemonic);
}
auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 4;
if(rd != 0){
auto res_val = (super::template sext<int64_t>(super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)) * super::template sext<int64_t>(super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0)));
auto Xtmp0_val = super::template zext<uint32_t>((res_val >> (32)));
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
}
this->do_sync(POST_SYNC, 53);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check
if(trap_state!=0){
auto& last_br = super::template get_reg<uint32_t>(arch::traits<ARCH>::LAST_BRANCH);
last_br = std::numeric_limits<uint32_t>::max();
super::core.enter_trap(trap_state, cur_pc_val);
}
pc.val=super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC);
return pc;
}
/* instruction 54: MULHSU */
compile_ret_t __mulhsu(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 54);
uint8_t rd = ((bit_sub<7,5>(instr)));
uint8_t rs1 = ((bit_sub<15,5>(instr)));
uint8_t rs2 = ((bit_sub<20,5>(instr)));
if(this->disass_enabled){
/* generate console output when executing the command */
auto mnemonic = fmt::format(
"{mnemonic:10} {rd}, {rs1}, {rs2}", fmt::arg("mnemonic", "mulhsu"),
fmt::arg("rd", name(rd)), fmt::arg("rs1", name(rs1)), fmt::arg("rs2", name(rs2)));
this->core.disass_output(pc.val, mnemonic);
}
auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 4;
if(rd != 0){
auto res_val = (super::template sext<int64_t>(super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)) * super::template zext<uint64_t>(super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0)));
auto Xtmp0_val = super::template zext<uint32_t>((res_val >> (32)));
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
}
this->do_sync(POST_SYNC, 54);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check
if(trap_state!=0){
auto& last_br = super::template get_reg<uint32_t>(arch::traits<ARCH>::LAST_BRANCH);
last_br = std::numeric_limits<uint32_t>::max();
super::core.enter_trap(trap_state, cur_pc_val);
}
pc.val=super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC);
return pc;
}
/* instruction 55: MULHU */
compile_ret_t __mulhu(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 55);
uint8_t rd = ((bit_sub<7,5>(instr)));
uint8_t rs1 = ((bit_sub<15,5>(instr)));
uint8_t rs2 = ((bit_sub<20,5>(instr)));
if(this->disass_enabled){
/* generate console output when executing the command */
auto mnemonic = fmt::format(
"{mnemonic:10} {rd}, {rs1}, {rs2}", fmt::arg("mnemonic", "mulhu"),
fmt::arg("rd", name(rd)), fmt::arg("rs1", name(rs1)), fmt::arg("rs2", name(rs2)));
this->core.disass_output(pc.val, mnemonic);
}
auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 4;
if(rd != 0){
auto res_val = (super::template zext<uint64_t>(super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)) * super::template zext<uint64_t>(super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0)));
auto Xtmp0_val = super::template zext<uint32_t>((res_val >> (32)));
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
}
this->do_sync(POST_SYNC, 55);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check
if(trap_state!=0){
auto& last_br = super::template get_reg<uint32_t>(arch::traits<ARCH>::LAST_BRANCH);
last_br = std::numeric_limits<uint32_t>::max();
super::core.enter_trap(trap_state, cur_pc_val);
}
pc.val=super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC);
return pc;
}
/* instruction 56: DIV */
compile_ret_t __div(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 56);
uint8_t rd = ((bit_sub<7,5>(instr)));
uint8_t rs1 = ((bit_sub<15,5>(instr)));
uint8_t rs2 = ((bit_sub<20,5>(instr)));
if(this->disass_enabled){
/* generate console output when executing the command */
auto mnemonic = fmt::format(
"{mnemonic:10} {rd}, {rs1}, {rs2}", fmt::arg("mnemonic", "div"),
fmt::arg("rd", name(rd)), fmt::arg("rs1", name(rs1)), fmt::arg("rs2", name(rs2)));
this->core.disass_output(pc.val, mnemonic);
}
auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 4;
if(rd != 0){
{
if((super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0) != 0)) {
uint32_t M1_val = - 1;
uint8_t XLM1_val = 32 - 1;
uint32_t ONE_val = 1;
uint32_t MMIN_val = ONE_val << XLM1_val;
{
if(((super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0) == MMIN_val) && (super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0) == M1_val))) {
auto Xtmp0_val = MMIN_val;
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
}
else {
auto Xtmp1_val = (static_cast<int32_t>(super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)) / static_cast<int32_t>(super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0)));
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp1_val;
}
}
}
else {
auto Xtmp2_val = -(1);
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp2_val;
}
}
}
this->do_sync(POST_SYNC, 56);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check
if(trap_state!=0){
auto& last_br = super::template get_reg<uint32_t>(arch::traits<ARCH>::LAST_BRANCH);
last_br = std::numeric_limits<uint32_t>::max();
super::core.enter_trap(trap_state, cur_pc_val);
}
pc.val=super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC);
return pc;
}
/* instruction 57: DIVU */
compile_ret_t __divu(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 57);
uint8_t rd = ((bit_sub<7,5>(instr)));
uint8_t rs1 = ((bit_sub<15,5>(instr)));
uint8_t rs2 = ((bit_sub<20,5>(instr)));
if(this->disass_enabled){
/* generate console output when executing the command */
auto mnemonic = fmt::format(
"{mnemonic:10} {rd}, {rs1}, {rs2}", fmt::arg("mnemonic", "divu"),
fmt::arg("rd", name(rd)), fmt::arg("rs1", name(rs1)), fmt::arg("rs2", name(rs2)));
this->core.disass_output(pc.val, mnemonic);
}
auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 4;
if(rd != 0){
{
if((super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0) != 0)) {
auto Xtmp0_val = (super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0) / super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0));
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
}
else {
auto Xtmp1_val = -(1);
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp1_val;
}
}
}
this->do_sync(POST_SYNC, 57);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check
if(trap_state!=0){
auto& last_br = super::template get_reg<uint32_t>(arch::traits<ARCH>::LAST_BRANCH);
last_br = std::numeric_limits<uint32_t>::max();
super::core.enter_trap(trap_state, cur_pc_val);
}
pc.val=super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC);
return pc;
}
/* instruction 58: REM */
compile_ret_t __rem(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 58);
uint8_t rd = ((bit_sub<7,5>(instr)));
uint8_t rs1 = ((bit_sub<15,5>(instr)));
uint8_t rs2 = ((bit_sub<20,5>(instr)));
if(this->disass_enabled){
/* generate console output when executing the command */
auto mnemonic = fmt::format(
"{mnemonic:10} {rd}, {rs1}, {rs2}", fmt::arg("mnemonic", "rem"),
fmt::arg("rd", name(rd)), fmt::arg("rs1", name(rs1)), fmt::arg("rs2", name(rs2)));
this->core.disass_output(pc.val, mnemonic);
}
auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 4;
if(rd != 0){
{
if((super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0) != 0)) {
uint32_t M1_val = - 1;
uint32_t XLM1_val = 32 - 1;
uint32_t ONE_val = 1;
uint32_t MMIN_val = ONE_val << XLM1_val;
{
if(((super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0) == MMIN_val) && (super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0) == M1_val))) {
auto Xtmp0_val = 0;
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
}
else {
auto Xtmp1_val = (static_cast<int32_t>(super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)) % static_cast<int32_t>(super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0)));
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp1_val;
}
}
}
else {
auto Xtmp2_val = super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0);
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp2_val;
}
}
}
this->do_sync(POST_SYNC, 58);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check
if(trap_state!=0){
auto& last_br = super::template get_reg<uint32_t>(arch::traits<ARCH>::LAST_BRANCH);
last_br = std::numeric_limits<uint32_t>::max();
super::core.enter_trap(trap_state, cur_pc_val);
}
pc.val=super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC);
return pc;
}
/* instruction 59: REMU */
compile_ret_t __remu(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 59);
uint8_t rd = ((bit_sub<7,5>(instr)));
uint8_t rs1 = ((bit_sub<15,5>(instr)));
uint8_t rs2 = ((bit_sub<20,5>(instr)));
if(this->disass_enabled){
/* generate console output when executing the command */
auto mnemonic = fmt::format(
"{mnemonic:10} {rd}, {rs1}, {rs2}", fmt::arg("mnemonic", "remu"),
fmt::arg("rd", name(rd)), fmt::arg("rs1", name(rs1)), fmt::arg("rs2", name(rs2)));
this->core.disass_output(pc.val, mnemonic);
}
auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 4;
if(rd != 0){
{
if((super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0) != 0)) {
auto Xtmp0_val = (super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0) % super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0));
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
}
else {
auto Xtmp1_val = super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0);
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp1_val;
}
}
}
this->do_sync(POST_SYNC, 59);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check
if(trap_state!=0){
auto& last_br = super::template get_reg<uint32_t>(arch::traits<ARCH>::LAST_BRANCH);
last_br = std::numeric_limits<uint32_t>::max();
super::core.enter_trap(trap_state, cur_pc_val);
}
pc.val=super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC);
return pc;
}
/* instruction 60: C.ADDI4SPN */
compile_ret_t __c_addi4spn(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 60);
uint8_t rd = ((bit_sub<2,3>(instr))); uint8_t rd = ((bit_sub<2,3>(instr)));
uint16_t imm = ((bit_sub<5,1>(instr) << 3) | (bit_sub<6,1>(instr) << 2) | (bit_sub<7,4>(instr) << 6) | (bit_sub<11,2>(instr) << 4)); uint16_t imm = ((bit_sub<5,1>(instr) << 3) | (bit_sub<6,1>(instr) << 2) | (bit_sub<7,4>(instr) << 6) | (bit_sub<11,2>(instr) << 4));
if(this->disass_enabled){ if(this->disass_enabled){
@@ -2072,7 +2413,7 @@ private:
} }
auto Xtmp0_val = (super::template get_reg<reg_t>(2 + traits<ARCH>::X0) + (imm)); auto Xtmp0_val = (super::template get_reg<reg_t>(2 + traits<ARCH>::X0) + (imm));
super::template get_reg<reg_t>(rd + 8 + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd + 8 + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 52); this->do_sync(POST_SYNC, 60);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2084,9 +2425,9 @@ private:
return pc; return pc;
} }
/* instruction 53: C.LW */ /* instruction 61: C.LW */
compile_ret_t __c_lw(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_lw(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 53); this->do_sync(PRE_SYNC, 61);
uint8_t rd = ((bit_sub<2,3>(instr))); uint8_t rd = ((bit_sub<2,3>(instr)));
uint8_t uimm = ((bit_sub<5,1>(instr) << 6) | (bit_sub<6,1>(instr) << 2) | (bit_sub<10,3>(instr) << 3)); uint8_t uimm = ((bit_sub<5,1>(instr) << 6) | (bit_sub<6,1>(instr) << 2) | (bit_sub<10,3>(instr) << 3));
@@ -2104,7 +2445,7 @@ private:
auto offs_val = (super::template get_reg<reg_t>(rs1 + 8 + traits<ARCH>::X0) + (uimm)); auto offs_val = (super::template get_reg<reg_t>(rs1 + 8 + traits<ARCH>::X0) + (uimm));
auto Xtmp0_val = super::template sext<int32_t>(super::template read_mem<uint32_t>(traits<ARCH>::MEM, offs_val)); auto Xtmp0_val = super::template sext<int32_t>(super::template read_mem<uint32_t>(traits<ARCH>::MEM, offs_val));
super::template get_reg<reg_t>(rd + 8 + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd + 8 + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 53); this->do_sync(POST_SYNC, 61);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2116,9 +2457,9 @@ private:
return pc; return pc;
} }
/* instruction 54: C.SW */ /* instruction 62: C.SW */
compile_ret_t __c_sw(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_sw(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 54); this->do_sync(PRE_SYNC, 62);
uint8_t rs2 = ((bit_sub<2,3>(instr))); uint8_t rs2 = ((bit_sub<2,3>(instr)));
uint8_t uimm = ((bit_sub<5,1>(instr) << 6) | (bit_sub<6,1>(instr) << 2) | (bit_sub<10,3>(instr) << 3)); uint8_t uimm = ((bit_sub<5,1>(instr) << 6) | (bit_sub<6,1>(instr) << 2) | (bit_sub<10,3>(instr) << 3));
@@ -2136,7 +2477,7 @@ private:
auto offs_val = (super::template get_reg<reg_t>(rs1 + 8 + traits<ARCH>::X0) + (uimm)); auto offs_val = (super::template get_reg<reg_t>(rs1 + 8 + traits<ARCH>::X0) + (uimm));
auto MEMtmp0_val = super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0); auto MEMtmp0_val = super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0);
super::write_mem(traits<ARCH>::MEM, offs_val, static_cast<uint32_t>(MEMtmp0_val)); super::write_mem(traits<ARCH>::MEM, offs_val, static_cast<uint32_t>(MEMtmp0_val));
this->do_sync(POST_SYNC, 54); this->do_sync(POST_SYNC, 62);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2148,9 +2489,9 @@ private:
return pc; return pc;
} }
/* instruction 55: C.ADDI */ /* instruction 63: C.ADDI */
compile_ret_t __c_addi(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_addi(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 55); this->do_sync(PRE_SYNC, 63);
int8_t imm = signextend<int8_t,6>((bit_sub<2,5>(instr)) | (bit_sub<12,1>(instr) << 5)); int8_t imm = signextend<int8_t,6>((bit_sub<2,5>(instr)) | (bit_sub<12,1>(instr) << 5));
uint8_t rs1 = ((bit_sub<7,5>(instr))); uint8_t rs1 = ((bit_sub<7,5>(instr)));
@@ -2166,7 +2507,7 @@ private:
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2; super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2;
auto Xtmp0_val = (static_cast<int32_t>(super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)) + (imm)); auto Xtmp0_val = (static_cast<int32_t>(super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)) + (imm));
super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 55); this->do_sync(POST_SYNC, 63);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2178,9 +2519,9 @@ private:
return pc; return pc;
} }
/* instruction 56: C.NOP */ /* instruction 64: C.NOP */
compile_ret_t __c_nop(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_nop(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 56); this->do_sync(PRE_SYNC, 64);
if(this->disass_enabled){ if(this->disass_enabled){
/* generate console output when executing the command */ /* generate console output when executing the command */
@@ -2190,7 +2531,7 @@ private:
auto cur_pc_val = pc.val; auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2; super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2;
/* TODO: describe operations for C.NOP ! */ /* TODO: describe operations for C.NOP ! */
this->do_sync(POST_SYNC, 56); this->do_sync(POST_SYNC, 64);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2202,9 +2543,9 @@ private:
return pc; return pc;
} }
/* instruction 57: C.JAL */ /* instruction 65: C.JAL */
compile_ret_t __c_jal(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_jal(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 57); this->do_sync(PRE_SYNC, 65);
int16_t imm = signextend<int16_t,12>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,3>(instr) << 1) | (bit_sub<6,1>(instr) << 7) | (bit_sub<7,1>(instr) << 6) | (bit_sub<8,1>(instr) << 10) | (bit_sub<9,2>(instr) << 8) | (bit_sub<11,1>(instr) << 4) | (bit_sub<12,1>(instr) << 11)); int16_t imm = signextend<int16_t,12>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,3>(instr) << 1) | (bit_sub<6,1>(instr) << 7) | (bit_sub<7,1>(instr) << 6) | (bit_sub<8,1>(instr) << 10) | (bit_sub<9,2>(instr) << 8) | (bit_sub<11,1>(instr) << 4) | (bit_sub<12,1>(instr) << 11));
if(this->disass_enabled){ if(this->disass_enabled){
@@ -2223,7 +2564,7 @@ private:
super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val; super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val;
auto is_cont_v = PC_val !=pc.val; auto is_cont_v = PC_val !=pc.val;
super::template get_reg(traits<ARCH>::LAST_BRANCH) = is_cont_v?1:0; super::template get_reg(traits<ARCH>::LAST_BRANCH) = is_cont_v?1:0;
this->do_sync(POST_SYNC, 57); this->do_sync(POST_SYNC, 65);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2235,9 +2576,9 @@ private:
return pc; return pc;
} }
/* instruction 58: C.LI */ /* instruction 66: C.LI */
compile_ret_t __c_li(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_li(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 58); this->do_sync(PRE_SYNC, 66);
int8_t imm = signextend<int8_t,6>((bit_sub<2,5>(instr)) | (bit_sub<12,1>(instr) << 5)); int8_t imm = signextend<int8_t,6>((bit_sub<2,5>(instr)) | (bit_sub<12,1>(instr) << 5));
uint8_t rd = ((bit_sub<7,5>(instr))); uint8_t rd = ((bit_sub<7,5>(instr)));
@@ -2256,7 +2597,7 @@ private:
} }
auto Xtmp0_val = (imm); auto Xtmp0_val = (imm);
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 58); this->do_sync(POST_SYNC, 66);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2268,9 +2609,9 @@ private:
return pc; return pc;
} }
/* instruction 59: C.LUI */ /* instruction 67: C.LUI */
compile_ret_t __c_lui(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_lui(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 59); this->do_sync(PRE_SYNC, 67);
int32_t imm = signextend<int32_t,18>((bit_sub<2,5>(instr) << 12) | (bit_sub<12,1>(instr) << 17)); int32_t imm = signextend<int32_t,18>((bit_sub<2,5>(instr) << 12) | (bit_sub<12,1>(instr) << 17));
uint8_t rd = ((bit_sub<7,5>(instr))); uint8_t rd = ((bit_sub<7,5>(instr)));
@@ -2292,7 +2633,7 @@ private:
} }
auto Xtmp0_val = (imm); auto Xtmp0_val = (imm);
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 59); this->do_sync(POST_SYNC, 67);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2304,9 +2645,9 @@ private:
return pc; return pc;
} }
/* instruction 60: C.ADDI16SP */ /* instruction 68: C.ADDI16SP */
compile_ret_t __c_addi16sp(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_addi16sp(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 60); this->do_sync(PRE_SYNC, 68);
int16_t imm = signextend<int16_t,10>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,2>(instr) << 7) | (bit_sub<5,1>(instr) << 6) | (bit_sub<6,1>(instr) << 4) | (bit_sub<12,1>(instr) << 9)); int16_t imm = signextend<int16_t,10>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,2>(instr) << 7) | (bit_sub<5,1>(instr) << 6) | (bit_sub<6,1>(instr) << 4) | (bit_sub<12,1>(instr) << 9));
if(this->disass_enabled){ if(this->disass_enabled){
@@ -2321,7 +2662,7 @@ private:
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2; super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2;
auto Xtmp0_val = (static_cast<int32_t>(super::template get_reg<reg_t>(2 + traits<ARCH>::X0)) + (imm)); auto Xtmp0_val = (static_cast<int32_t>(super::template get_reg<reg_t>(2 + traits<ARCH>::X0)) + (imm));
super::template get_reg<reg_t>(2 + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(2 + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 60); this->do_sync(POST_SYNC, 68);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2333,9 +2674,9 @@ private:
return pc; return pc;
} }
/* instruction 61: C.SRLI */ /* instruction 69: C.SRLI */
compile_ret_t __c_srli(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_srli(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 61); this->do_sync(PRE_SYNC, 69);
uint8_t shamt = ((bit_sub<2,5>(instr))); uint8_t shamt = ((bit_sub<2,5>(instr)));
uint8_t rs1 = ((bit_sub<7,3>(instr))); uint8_t rs1 = ((bit_sub<7,3>(instr)));
@@ -2352,7 +2693,7 @@ private:
uint8_t rs1_idx_val = rs1 + 8; uint8_t rs1_idx_val = rs1 + 8;
auto Xtmp0_val = (static_cast<uint32_t>(super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0))>>(shamt)); auto Xtmp0_val = (static_cast<uint32_t>(super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0))>>(shamt));
super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 61); this->do_sync(POST_SYNC, 69);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2364,9 +2705,9 @@ private:
return pc; return pc;
} }
/* instruction 62: C.SRAI */ /* instruction 70: C.SRAI */
compile_ret_t __c_srai(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_srai(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 62); this->do_sync(PRE_SYNC, 70);
uint8_t shamt = ((bit_sub<2,5>(instr))); uint8_t shamt = ((bit_sub<2,5>(instr)));
uint8_t rs1 = ((bit_sub<7,3>(instr))); uint8_t rs1 = ((bit_sub<7,3>(instr)));
@@ -2383,7 +2724,7 @@ private:
uint8_t rs1_idx_val = rs1 + 8; uint8_t rs1_idx_val = rs1 + 8;
auto Xtmp0_val = (static_cast<int32_t>(super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0))>>(shamt)); auto Xtmp0_val = (static_cast<int32_t>(super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0))>>(shamt));
super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 62); this->do_sync(POST_SYNC, 70);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2395,9 +2736,9 @@ private:
return pc; return pc;
} }
/* instruction 63: C.ANDI */ /* instruction 71: C.ANDI */
compile_ret_t __c_andi(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_andi(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 63); this->do_sync(PRE_SYNC, 71);
int8_t imm = signextend<int8_t,6>((bit_sub<2,5>(instr)) | (bit_sub<12,1>(instr) << 5)); int8_t imm = signextend<int8_t,6>((bit_sub<2,5>(instr)) | (bit_sub<12,1>(instr) << 5));
uint8_t rs1 = ((bit_sub<7,3>(instr))); uint8_t rs1 = ((bit_sub<7,3>(instr)));
@@ -2414,7 +2755,7 @@ private:
uint8_t rs1_idx_val = rs1 + 8; uint8_t rs1_idx_val = rs1 + 8;
auto Xtmp0_val = (static_cast<int32_t>(super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0)) & (imm)); auto Xtmp0_val = (static_cast<int32_t>(super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0)) & (imm));
super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rs1_idx_val + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 63); this->do_sync(POST_SYNC, 71);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2426,9 +2767,9 @@ private:
return pc; return pc;
} }
/* instruction 64: C.SUB */ /* instruction 72: C.SUB */
compile_ret_t __c_sub(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_sub(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 64); this->do_sync(PRE_SYNC, 72);
uint8_t rs2 = ((bit_sub<2,3>(instr))); uint8_t rs2 = ((bit_sub<2,3>(instr)));
uint8_t rd = ((bit_sub<7,3>(instr))); uint8_t rd = ((bit_sub<7,3>(instr)));
@@ -2445,7 +2786,7 @@ private:
uint8_t rd_idx_val = rd + 8; uint8_t rd_idx_val = rd + 8;
auto Xtmp0_val = (super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0) - super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0)); auto Xtmp0_val = (super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0) - super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0));
super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 64); this->do_sync(POST_SYNC, 72);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2457,9 +2798,9 @@ private:
return pc; return pc;
} }
/* instruction 65: C.XOR */ /* instruction 73: C.XOR */
compile_ret_t __c_xor(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_xor(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 65); this->do_sync(PRE_SYNC, 73);
uint8_t rs2 = ((bit_sub<2,3>(instr))); uint8_t rs2 = ((bit_sub<2,3>(instr)));
uint8_t rd = ((bit_sub<7,3>(instr))); uint8_t rd = ((bit_sub<7,3>(instr)));
@@ -2476,7 +2817,7 @@ private:
uint8_t rd_idx_val = rd + 8; uint8_t rd_idx_val = rd + 8;
auto Xtmp0_val = (super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0) ^ super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0)); auto Xtmp0_val = (super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0) ^ super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0));
super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 65); this->do_sync(POST_SYNC, 73);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2488,9 +2829,9 @@ private:
return pc; return pc;
} }
/* instruction 66: C.OR */ /* instruction 74: C.OR */
compile_ret_t __c_or(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_or(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 66); this->do_sync(PRE_SYNC, 74);
uint8_t rs2 = ((bit_sub<2,3>(instr))); uint8_t rs2 = ((bit_sub<2,3>(instr)));
uint8_t rd = ((bit_sub<7,3>(instr))); uint8_t rd = ((bit_sub<7,3>(instr)));
@@ -2507,7 +2848,7 @@ private:
uint8_t rd_idx_val = rd + 8; uint8_t rd_idx_val = rd + 8;
auto Xtmp0_val = (super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0) | super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0)); auto Xtmp0_val = (super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0) | super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0));
super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 66); this->do_sync(POST_SYNC, 74);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2519,9 +2860,9 @@ private:
return pc; return pc;
} }
/* instruction 67: C.AND */ /* instruction 75: C.AND */
compile_ret_t __c_and(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_and(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 67); this->do_sync(PRE_SYNC, 75);
uint8_t rs2 = ((bit_sub<2,3>(instr))); uint8_t rs2 = ((bit_sub<2,3>(instr)));
uint8_t rd = ((bit_sub<7,3>(instr))); uint8_t rd = ((bit_sub<7,3>(instr)));
@@ -2538,7 +2879,7 @@ private:
uint8_t rd_idx_val = rd + 8; uint8_t rd_idx_val = rd + 8;
auto Xtmp0_val = (super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0) & super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0)); auto Xtmp0_val = (super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0) & super::template get_reg<reg_t>(rs2 + 8 + traits<ARCH>::X0));
super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd_idx_val + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 67); this->do_sync(POST_SYNC, 75);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2550,9 +2891,9 @@ private:
return pc; return pc;
} }
/* instruction 68: C.J */ /* instruction 76: C.J */
compile_ret_t __c_j(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_j(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 68); this->do_sync(PRE_SYNC, 76);
int16_t imm = signextend<int16_t,12>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,3>(instr) << 1) | (bit_sub<6,1>(instr) << 7) | (bit_sub<7,1>(instr) << 6) | (bit_sub<8,1>(instr) << 10) | (bit_sub<9,2>(instr) << 8) | (bit_sub<11,1>(instr) << 4) | (bit_sub<12,1>(instr) << 11)); int16_t imm = signextend<int16_t,12>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,3>(instr) << 1) | (bit_sub<6,1>(instr) << 7) | (bit_sub<7,1>(instr) << 6) | (bit_sub<8,1>(instr) << 10) | (bit_sub<9,2>(instr) << 8) | (bit_sub<11,1>(instr) << 4) | (bit_sub<12,1>(instr) << 11));
if(this->disass_enabled){ if(this->disass_enabled){
@@ -2569,7 +2910,7 @@ private:
super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val; super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val;
auto is_cont_v = PC_val !=pc.val; auto is_cont_v = PC_val !=pc.val;
super::template get_reg(traits<ARCH>::LAST_BRANCH) = is_cont_v?1:0; super::template get_reg(traits<ARCH>::LAST_BRANCH) = is_cont_v?1:0;
this->do_sync(POST_SYNC, 68); this->do_sync(POST_SYNC, 76);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2581,9 +2922,9 @@ private:
return pc; return pc;
} }
/* instruction 69: C.BEQZ */ /* instruction 77: C.BEQZ */
compile_ret_t __c_beqz(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_beqz(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 69); this->do_sync(PRE_SYNC, 77);
int16_t imm = signextend<int16_t,9>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,2>(instr) << 1) | (bit_sub<5,2>(instr) << 6) | (bit_sub<10,2>(instr) << 3) | (bit_sub<12,1>(instr) << 8)); int16_t imm = signextend<int16_t,9>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,2>(instr) << 1) | (bit_sub<5,2>(instr) << 6) | (bit_sub<10,2>(instr) << 3) | (bit_sub<12,1>(instr) << 8));
uint8_t rs1 = ((bit_sub<7,3>(instr))); uint8_t rs1 = ((bit_sub<7,3>(instr)));
@@ -2603,7 +2944,7 @@ private:
super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val; super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val;
auto is_cont_v = PC_val !=pc.val; auto is_cont_v = PC_val !=pc.val;
super::template get_reg(traits<ARCH>::LAST_BRANCH) = is_cont_v?1:0; super::template get_reg(traits<ARCH>::LAST_BRANCH) = is_cont_v?1:0;
this->do_sync(POST_SYNC, 69); this->do_sync(POST_SYNC, 77);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2615,9 +2956,9 @@ private:
return pc; return pc;
} }
/* instruction 70: C.BNEZ */ /* instruction 78: C.BNEZ */
compile_ret_t __c_bnez(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_bnez(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 70); this->do_sync(PRE_SYNC, 78);
int16_t imm = signextend<int16_t,9>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,2>(instr) << 1) | (bit_sub<5,2>(instr) << 6) | (bit_sub<10,2>(instr) << 3) | (bit_sub<12,1>(instr) << 8)); int16_t imm = signextend<int16_t,9>((bit_sub<2,1>(instr) << 5) | (bit_sub<3,2>(instr) << 1) | (bit_sub<5,2>(instr) << 6) | (bit_sub<10,2>(instr) << 3) | (bit_sub<12,1>(instr) << 8));
uint8_t rs1 = ((bit_sub<7,3>(instr))); uint8_t rs1 = ((bit_sub<7,3>(instr)));
@@ -2637,7 +2978,7 @@ private:
super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val; super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val;
auto is_cont_v = PC_val !=pc.val; auto is_cont_v = PC_val !=pc.val;
super::template get_reg(traits<ARCH>::LAST_BRANCH) = is_cont_v?1:0; super::template get_reg(traits<ARCH>::LAST_BRANCH) = is_cont_v?1:0;
this->do_sync(POST_SYNC, 70); this->do_sync(POST_SYNC, 78);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2649,9 +2990,9 @@ private:
return pc; return pc;
} }
/* instruction 71: C.SLLI */ /* instruction 79: C.SLLI */
compile_ret_t __c_slli(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_slli(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 71); this->do_sync(PRE_SYNC, 79);
uint8_t shamt = ((bit_sub<2,5>(instr))); uint8_t shamt = ((bit_sub<2,5>(instr)));
uint8_t rs1 = ((bit_sub<7,5>(instr))); uint8_t rs1 = ((bit_sub<7,5>(instr)));
@@ -2670,7 +3011,7 @@ private:
} }
auto Xtmp0_val = (super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)<<(shamt)); auto Xtmp0_val = (super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)<<(shamt));
super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 71); this->do_sync(POST_SYNC, 79);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2682,9 +3023,9 @@ private:
return pc; return pc;
} }
/* instruction 72: C.LWSP */ /* instruction 80: C.LWSP */
compile_ret_t __c_lwsp(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_lwsp(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 72); this->do_sync(PRE_SYNC, 80);
uint8_t uimm = ((bit_sub<2,2>(instr) << 6) | (bit_sub<4,3>(instr) << 2) | (bit_sub<12,1>(instr) << 5)); uint8_t uimm = ((bit_sub<2,2>(instr) << 6) | (bit_sub<4,3>(instr) << 2) | (bit_sub<12,1>(instr) << 5));
uint8_t rd = ((bit_sub<7,5>(instr))); uint8_t rd = ((bit_sub<7,5>(instr)));
@@ -2701,7 +3042,7 @@ private:
auto offs_val = (super::template get_reg<reg_t>(2 + traits<ARCH>::X0) + (uimm)); auto offs_val = (super::template get_reg<reg_t>(2 + traits<ARCH>::X0) + (uimm));
auto Xtmp0_val = super::template sext<int32_t>(super::template read_mem<uint32_t>(traits<ARCH>::MEM, offs_val)); auto Xtmp0_val = super::template sext<int32_t>(super::template read_mem<uint32_t>(traits<ARCH>::MEM, offs_val));
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 72); this->do_sync(POST_SYNC, 80);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2713,9 +3054,9 @@ private:
return pc; return pc;
} }
/* instruction 73: C.MV */ /* instruction 81: C.MV */
compile_ret_t __c_mv(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_mv(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 73); this->do_sync(PRE_SYNC, 81);
uint8_t rs2 = ((bit_sub<2,5>(instr))); uint8_t rs2 = ((bit_sub<2,5>(instr)));
uint8_t rd = ((bit_sub<7,5>(instr))); uint8_t rd = ((bit_sub<7,5>(instr)));
@@ -2731,7 +3072,7 @@ private:
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2; super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2;
auto Xtmp0_val = super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0); auto Xtmp0_val = super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0);
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 73); this->do_sync(POST_SYNC, 81);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2743,9 +3084,9 @@ private:
return pc; return pc;
} }
/* instruction 74: C.JR */ /* instruction 82: C.JR */
compile_ret_t __c_jr(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_jr(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 74); this->do_sync(PRE_SYNC, 82);
uint8_t rs1 = ((bit_sub<7,5>(instr))); uint8_t rs1 = ((bit_sub<7,5>(instr)));
if(this->disass_enabled){ if(this->disass_enabled){
@@ -2761,7 +3102,7 @@ private:
auto PC_val = super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0); auto PC_val = super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0);
super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val; super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val;
super::template get_reg(traits<ARCH>::LAST_BRANCH) = std::numeric_limits<uint32_t>::max(); super::template get_reg(traits<ARCH>::LAST_BRANCH) = std::numeric_limits<uint32_t>::max();
this->do_sync(POST_SYNC, 74); this->do_sync(POST_SYNC, 82);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2773,9 +3114,9 @@ private:
return pc; return pc;
} }
/* instruction 75: C.ADD */ /* instruction 83: C.ADD */
compile_ret_t __c_add(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_add(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 75); this->do_sync(PRE_SYNC, 83);
uint8_t rs2 = ((bit_sub<2,5>(instr))); uint8_t rs2 = ((bit_sub<2,5>(instr)));
uint8_t rd = ((bit_sub<7,5>(instr))); uint8_t rd = ((bit_sub<7,5>(instr)));
@@ -2791,7 +3132,7 @@ private:
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2; super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2;
auto Xtmp0_val = (super::template get_reg<reg_t>(rd + traits<ARCH>::X0) + super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0)); auto Xtmp0_val = (super::template get_reg<reg_t>(rd + traits<ARCH>::X0) + super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0));
super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val; super::template get_reg<reg_t>(rd + traits<ARCH>::X0)=Xtmp0_val;
this->do_sync(POST_SYNC, 75); this->do_sync(POST_SYNC, 83);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2803,9 +3144,9 @@ private:
return pc; return pc;
} }
/* instruction 76: C.JALR */ /* instruction 84: C.JALR */
compile_ret_t __c_jalr(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_jalr(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 76); this->do_sync(PRE_SYNC, 84);
uint8_t rs1 = ((bit_sub<7,5>(instr))); uint8_t rs1 = ((bit_sub<7,5>(instr)));
if(this->disass_enabled){ if(this->disass_enabled){
@@ -2823,7 +3164,7 @@ private:
auto PC_val = super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0); auto PC_val = super::template get_reg<reg_t>(rs1 + traits<ARCH>::X0);
super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val; super::template get_reg(traits<ARCH>::NEXT_PC) = PC_val;
super::template get_reg(traits<ARCH>::LAST_BRANCH) = std::numeric_limits<uint32_t>::max(); super::template get_reg(traits<ARCH>::LAST_BRANCH) = std::numeric_limits<uint32_t>::max();
this->do_sync(POST_SYNC, 76); this->do_sync(POST_SYNC, 84);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2835,9 +3176,9 @@ private:
return pc; return pc;
} }
/* instruction 77: C.EBREAK */ /* instruction 85: C.EBREAK */
compile_ret_t __c_ebreak(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_ebreak(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 77); this->do_sync(PRE_SYNC, 85);
if(this->disass_enabled){ if(this->disass_enabled){
/* generate console output when executing the command */ /* generate console output when executing the command */
@@ -2847,7 +3188,7 @@ private:
auto cur_pc_val = pc.val; auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2; super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2;
raise_trap(0, 3); raise_trap(0, 3);
this->do_sync(POST_SYNC, 77); this->do_sync(POST_SYNC, 85);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2859,9 +3200,9 @@ private:
return pc; return pc;
} }
/* instruction 78: C.SWSP */ /* instruction 86: C.SWSP */
compile_ret_t __c_swsp(virt_addr_t& pc, code_word_t instr){ compile_ret_t __c_swsp(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 78); this->do_sync(PRE_SYNC, 86);
uint8_t rs2 = ((bit_sub<2,5>(instr))); uint8_t rs2 = ((bit_sub<2,5>(instr)));
uint8_t uimm = ((bit_sub<7,2>(instr) << 6) | (bit_sub<9,4>(instr) << 2)); uint8_t uimm = ((bit_sub<7,2>(instr) << 6) | (bit_sub<9,4>(instr) << 2));
@@ -2878,7 +3219,7 @@ private:
auto offs_val = (super::template get_reg<reg_t>(2 + traits<ARCH>::X0) + (uimm)); auto offs_val = (super::template get_reg<reg_t>(2 + traits<ARCH>::X0) + (uimm));
auto MEMtmp0_val = super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0); auto MEMtmp0_val = super::template get_reg<reg_t>(rs2 + traits<ARCH>::X0);
super::write_mem(traits<ARCH>::MEM, offs_val, static_cast<uint32_t>(MEMtmp0_val)); super::write_mem(traits<ARCH>::MEM, offs_val, static_cast<uint32_t>(MEMtmp0_val));
this->do_sync(POST_SYNC, 78); this->do_sync(POST_SYNC, 86);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2890,9 +3231,9 @@ private:
return pc; return pc;
} }
/* instruction 79: DII */ /* instruction 87: DII */
compile_ret_t __dii(virt_addr_t& pc, code_word_t instr){ compile_ret_t __dii(virt_addr_t& pc, code_word_t instr){
this->do_sync(PRE_SYNC, 79); this->do_sync(PRE_SYNC, 87);
if(this->disass_enabled){ if(this->disass_enabled){
/* generate console output when executing the command */ /* generate console output when executing the command */
@@ -2902,7 +3243,7 @@ private:
auto cur_pc_val = pc.val; auto cur_pc_val = pc.val;
super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2; super::template get_reg<reg_t>(arch::traits<ARCH>::NEXT_PC) = cur_pc_val + 2;
raise_trap(0, 2); raise_trap(0, 2);
this->do_sync(POST_SYNC, 79); this->do_sync(POST_SYNC, 87);
auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE); auto& trap_state = super::template get_reg<uint32_t>(arch::traits<ARCH>::TRAP_STATE);
// trap check // trap check
if(trap_state!=0){ if(trap_state!=0){
@@ -2973,8 +3314,8 @@ typename vm_base<ARCH>::virt_addr_t vm_impl<ARCH>::execute_inst(virt_addr_t star
} // namespace mnrv32 } // namespace mnrv32
template <> template <>
std::unique_ptr<vm_if> create<arch::mnrv32>(arch::mnrv32 *core, unsigned short port, bool dump) { std::unique_ptr<vm_if> create<arch::tgf_c>(arch::tgf_c *core, unsigned short port, bool dump) {
auto ret = new mnrv32::vm_impl<arch::mnrv32>(*core, dump); auto ret = new tgf_c::vm_impl<arch::tgf_c>(*core, dump);
if (port != 0) debugger::server<debugger::gdb_session>::run_server(ret, port); if (port != 0) debugger::server<debugger::gdb_session>::run_server(ret, port);
return std::unique_ptr<vm_if>(ret); return std::unique_ptr<vm_if>(ret);
} }

109
src/vm/llvm/fp_impl.cpp Normal file
View File

@@ -0,0 +1,109 @@
////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2017, MINRES Technologies GmbH
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are met:
//
// 1. Redistributions of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
//
// 2. Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
//
// 3. Neither the name of the copyright holder nor the names of its contributors
// may be used to endorse or promote products derived from this software
// without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
// Contributors:
// eyck@minres.com - initial API and implementation
////////////////////////////////////////////////////////////////////////////////
#include <iss/iss.h>
#include <iss/llvm/vm_base.h>
extern "C" {
#include <softfloat.h>
#include "internals.h"
#include "specialize.h"
}
#include <limits>
namespace iss {
namespace llvm {
namespace fp_impl {
using namespace std;
using namespace ::llvm;
#define INT_TYPE(L) Type::getIntNTy(mod->getContext(), L)
#define FLOAT_TYPE Type::getFloatTy(mod->getContext())
#define DOUBLE_TYPE Type::getDoubleTy(mod->getContext())
#define VOID_TYPE Type::getVoidTy(mod->getContext())
#define THIS_PTR_TYPE Type::getIntNPtrTy(mod->getContext(), 8)
#define FDECLL(NAME, RET, ...) \
Function *NAME##_func = CurrentModule->getFunction(#NAME); \
if (!NAME##_func) { \
std::vector<Type *> NAME##_args{__VA_ARGS__}; \
FunctionType *NAME##_type = FunctionType::get(RET, NAME##_args, false); \
NAME##_func = Function::Create(NAME##_type, GlobalValue::ExternalLinkage, #NAME, CurrentModule); \
NAME##_func->setCallingConv(CallingConv::C); \
}
#define FDECL(NAME, RET, ...) \
std::vector<Type *> NAME##_args{__VA_ARGS__}; \
FunctionType *NAME##_type = FunctionType::get(RET, NAME##_args, false); \
mod->getOrInsertFunction(#NAME, NAME##_type);
void add_fp_functions_2_module(Module *mod, uint32_t flen, uint32_t xlen) {
if(flen){
FDECL(fget_flags, INT_TYPE(32));
FDECL(fadd_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fsub_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fmul_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fdiv_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fsqrt_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fcmp_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(32));
FDECL(fcvt_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fmadd_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fsel_s, INT_TYPE(32), INT_TYPE(32), INT_TYPE(32), INT_TYPE(32));
FDECL(fclass_s, INT_TYPE(32), INT_TYPE(32));
FDECL(fcvt_32_64, INT_TYPE(64), INT_TYPE(32), INT_TYPE(32), INT_TYPE(8));
FDECL(fcvt_64_32, INT_TYPE(32), INT_TYPE(64), INT_TYPE(32), INT_TYPE(8));
if(flen>32){
FDECL(fconv_d2f, INT_TYPE(32), INT_TYPE(64), INT_TYPE(8));
FDECL(fconv_f2d, INT_TYPE(64), INT_TYPE(32), INT_TYPE(8));
FDECL(fadd_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fsub_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fmul_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fdiv_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fsqrt_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(8));
FDECL(fcmp_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(32));
FDECL(fcvt_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(32), INT_TYPE(8));
FDECL(fmadd_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(32), INT_TYPE(8));
FDECL(fsel_d, INT_TYPE(64), INT_TYPE(64), INT_TYPE(64), INT_TYPE(32));
FDECL(fclass_d, INT_TYPE(64), INT_TYPE(64));
FDECL(unbox_s, INT_TYPE(32), INT_TYPE(64));
}
}
}
}
}
}

8895
src/vm/llvm/vm_rv32gc.cpp
View File

File diff suppressed because it is too large Load Diff

11371
src/vm/llvm/vm_rv64gc.cpp
View File

File diff suppressed because it is too large Load Diff

3154
src/vm/llvm/vm_rv64i.cpp
View File

File diff suppressed because it is too large Load Diff

12
src/vm/llvm/vm_mnrv32.cpp → src/vm/llvm/vm_tgf_b.cpp
View File

@@ -30,8 +30,8 @@
* *
*******************************************************************************/ *******************************************************************************/
#include <iss/arch/mnrv32.h> #include <iss/arch/tgf_b.h>
#include <iss/arch/riscv_hart_msu_vp.h> #include <iss/arch/riscv_hart_m_p.h>
#include <iss/debugger/gdb_session.h> #include <iss/debugger/gdb_session.h>
#include <iss/debugger/server.h> #include <iss/debugger/server.h>
#include <iss/iss.h> #include <iss/iss.h>
@@ -52,7 +52,7 @@ namespace fp_impl {
void add_fp_functions_2_module(::llvm::Module *, unsigned, unsigned); void add_fp_functions_2_module(::llvm::Module *, unsigned, unsigned);
} }
namespace mnrv32 { namespace tgf_b {
using namespace ::llvm; using namespace ::llvm;
using namespace iss::arch; using namespace iss::arch;
using namespace iss::debugger; using namespace iss::debugger;
@@ -2570,11 +2570,11 @@ template <typename ARCH> inline void vm_impl<ARCH>::gen_trap_check(BasicBlock *b
bb, this->trap_blk, 1); bb, this->trap_blk, 1);
} }
} // namespace mnrv32 } // namespace tgf_b
template <> template <>
std::unique_ptr<vm_if> create<arch::mnrv32>(arch::mnrv32 *core, unsigned short port, bool dump) { std::unique_ptr<vm_if> create<arch::tgf_b>(arch::tgf_b *core, unsigned short port, bool dump) {
auto ret = new mnrv32::vm_impl<arch::mnrv32>(*core, dump); auto ret = new tgf_b::vm_impl<arch::tgf_b>(*core, dump);
if (port != 0) debugger::server<debugger::gdb_session>::run_server(ret, port); if (port != 0) debugger::server<debugger::gdb_session>::run_server(ret, port);
return std::unique_ptr<vm_if>(ret); return std::unique_ptr<vm_if>(ret);
} }

4802
src/vm/llvm/vm_rv32imac.cpp → src/vm/llvm/vm_tgf_c.cpp
View File

File diff suppressed because it is too large Load Diff

1273
src/vm/tcc/vm_rv32gc.cpp
View File

File diff suppressed because it is too large Load Diff

913
src/vm/tcc/vm_rv32imac.cpp
View File

@@ -1,913 +0,0 @@
/*******************************************************************************
* Copyright (C) 2020 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*******************************************************************************/
#include <iss/arch/rv32imac.h>
#include <iss/arch/riscv_hart_msu_vp.h>
#include <iss/debugger/gdb_session.h>
#include <iss/debugger/server.h>
#include <iss/iss.h>
#include <iss/llvm/vm_base.h>
#include <util/logging.h>
#ifndef FMT_HEADER_ONLY
#define FMT_HEADER_ONLY
#endif
#include <fmt/format.h>
#include <array>
#include <iss/debugger/riscv_target_adapter.h>
namespace iss {
namespace vm {
namespace fp_impl {
void add_fp_functions_2_module(llvm::Module *, unsigned, unsigned);
}
}
namespace tcc {
namespace rv32imac {
using namespace iss::arch;
using namespace iss::debugger;
using namespace iss::vm::llvm;
template <typename ARCH> class vm_impl : public vm_base<ARCH> {
public:
using super = typename iss::vm::llvm::vm_base<ARCH>;
using virt_addr_t = typename super::virt_addr_t;
using phys_addr_t = typename super::phys_addr_t;
using code_word_t = typename super::code_word_t;
using addr_t = typename super::addr_t;
vm_impl();
vm_impl(ARCH &core, unsigned core_id = 0, unsigned cluster_id = 0);
void enableDebug(bool enable) { super::sync_exec = super::ALL_SYNC; }
target_adapter_if *accquire_target_adapter(server_if *srv) override {
debugger_if::dbg_enabled = true;
if (vm_base<ARCH>::tgt_adapter == nullptr)
vm_base<ARCH>::tgt_adapter = new riscv_target_adapter<ARCH>(srv, this->get_arch());
return vm_base<ARCH>::tgt_adapter;
}
protected:
using vm_base<ARCH>::get_reg_ptr;
using this_class = vm_impl<ARCH>;
using compile_ret_t = std::tuple<continuation_e>;
using compile_func = compile_ret_t (this_class::*)(virt_addr_t &pc, code_word_t instr, std::ostringstream&);
inline const char *name(size_t index){return traits<ARCH>::reg_aliases.at(index);}
template <typename T> inline ConstantInt *size(T type) {
return ConstantInt::get(getContext(), APInt(32, type->getType()->getScalarSizeInBits()));
}
void setup_module(Module* m) override {
super::setup_module(m);
iss::vm::fp_impl::add_fp_functions_2_module(m, traits<ARCH>::FP_REGS_SIZE, traits<ARCH>::XLEN);
}
inline Value *gen_choose(Value *cond, Value *trueVal, Value *falseVal, unsigned size) {
return super::gen_cond_assign(cond, this->gen_ext(trueVal, size), this->gen_ext(falseVal, size));
}
compile_ret_t gen_single_inst_behavior(virt_addr_t &, unsigned int &, std::ostringstream&) override;
void gen_leave_behavior(BasicBlock *leave_blk) override;
void gen_raise_trap(uint16_t trap_id, uint16_t cause);
void gen_leave_trap(unsigned lvl);
void gen_wait(unsigned type);
void gen_trap_behavior(BasicBlock *) override;
void gen_trap_check(BasicBlock *bb);
inline Value *gen_reg_load(unsigned i, unsigned level = 0) {
return this->builder.CreateLoad(get_reg_ptr(i), false);
}
inline void gen_set_pc(virt_addr_t pc, unsigned reg_num) {
Value *next_pc_v = this->builder.CreateSExtOrTrunc(this->gen_const(traits<ARCH>::XLEN, pc.val),
this->get_type(traits<ARCH>::XLEN));
this->builder.CreateStore(next_pc_v, get_reg_ptr(reg_num), true);
}
// some compile time constants
// enum { MASK16 = 0b1111110001100011, MASK32 = 0b11111111111100000111000001111111 };
enum { MASK16 = 0b1111111111111111, MASK32 = 0b11111111111100000111000001111111 };
enum { EXTR_MASK16 = MASK16 >> 2, EXTR_MASK32 = MASK32 >> 2 };
enum { LUT_SIZE = 1 << util::bit_count(EXTR_MASK32), LUT_SIZE_C = 1 << util::bit_count(EXTR_MASK16) };
std::array<compile_func, LUT_SIZE> lut;
std::array<compile_func, LUT_SIZE_C> lut_00, lut_01, lut_10;
std::array<compile_func, LUT_SIZE> lut_11;
std::array<compile_func *, 4> qlut;
std::array<const uint32_t, 4> lutmasks = {{EXTR_MASK16, EXTR_MASK16, EXTR_MASK16, EXTR_MASK32}};
void expand_bit_mask(int pos, uint32_t mask, uint32_t value, uint32_t valid, uint32_t idx, compile_func lut[],
compile_func f) {
if (pos < 0) {
lut[idx] = f;
} else {
auto bitmask = 1UL << pos;
if ((mask & bitmask) == 0) {
expand_bit_mask(pos - 1, mask, value, valid, idx, lut, f);
} else {
if ((valid & bitmask) == 0) {
expand_bit_mask(pos - 1, mask, value, valid, (idx << 1), lut, f);
expand_bit_mask(pos - 1, mask, value, valid, (idx << 1) + 1, lut, f);
} else {
auto new_val = idx << 1;
if ((value & bitmask) != 0) new_val++;
expand_bit_mask(pos - 1, mask, value, valid, new_val, lut, f);
}
}
}
}
inline uint32_t extract_fields(uint32_t val) { return extract_fields(29, val >> 2, lutmasks[val & 0x3], 0); }
uint32_t extract_fields(int pos, uint32_t val, uint32_t mask, uint32_t lut_val) {
if (pos >= 0) {
auto bitmask = 1UL << pos;
if ((mask & bitmask) == 0) {
lut_val = extract_fields(pos - 1, val, mask, lut_val);
} else {
auto new_val = lut_val << 1;
if ((val & bitmask) != 0) new_val++;
lut_val = extract_fields(pos - 1, val, mask, new_val);
}
}
return lut_val;
}
private:
/****************************************************************************
* start opcode definitions
****************************************************************************/
struct InstructionDesriptor {
size_t length;
uint32_t value;
uint32_t mask;
compile_func op;
};
const std::array<InstructionDesriptor, 99> instr_descr = {{
/* entries are: size, valid value, valid mask, function ptr */
/* instruction JALR */
{32, 0b00000000000000000000000001100111, 0b00000000000000000111000001111111, &this_class::__jalr},
/* instruction C.ADDI4SPN */
{16, 0b0000000000000000, 0b1110000000000011, &this_class::__c_addi4spn},
/* instruction C.LW */
{16, 0b0100000000000000, 0b1110000000000011, &this_class::__c_lw},
/* instruction C.SW */
{16, 0b1100000000000000, 0b1110000000000011, &this_class::__c_sw},
/* instruction C.ADDI */
{16, 0b0000000000000001, 0b1110000000000011, &this_class::__c_addi},
/* instruction C.NOP */
{16, 0b0000000000000001, 0b1111111111111111, &this_class::__c_nop},
/* instruction C.JAL */
{16, 0b0010000000000001, 0b1110000000000011, &this_class::__c_jal},
/* instruction C.LI */
{16, 0b0100000000000001, 0b1110000000000011, &this_class::__c_li},
/* instruction C.LUI */
{16, 0b0110000000000001, 0b1110000000000011, &this_class::__c_lui},
/* instruction C.ADDI16SP */
{16, 0b0110000100000001, 0b1110111110000011, &this_class::__c_addi16sp},
/* instruction C.SRLI */
{16, 0b1000000000000001, 0b1111110000000011, &this_class::__c_srli},
/* instruction C.SRAI */
{16, 0b1000010000000001, 0b1111110000000011, &this_class::__c_srai},
/* instruction C.ANDI */
{16, 0b1000100000000001, 0b1110110000000011, &this_class::__c_andi},
/* instruction C.SUB */
{16, 0b1000110000000001, 0b1111110001100011, &this_class::__c_sub},
/* instruction C.XOR */
{16, 0b1000110000100001, 0b1111110001100011, &this_class::__c_xor},
/* instruction C.OR */
{16, 0b1000110001000001, 0b1111110001100011, &this_class::__c_or},
/* instruction C.AND */
{16, 0b1000110001100001, 0b1111110001100011, &this_class::__c_and},
/* instruction C.J */
{16, 0b1010000000000001, 0b1110000000000011, &this_class::__c_j},
/* instruction C.BEQZ */
{16, 0b1100000000000001, 0b1110000000000011, &this_class::__c_beqz},
/* instruction C.BNEZ */
{16, 0b1110000000000001, 0b1110000000000011, &this_class::__c_bnez},
/* instruction C.SLLI */
{16, 0b0000000000000010, 0b1111000000000011, &this_class::__c_slli},
/* instruction C.LWSP */
{16, 0b0100000000000010, 0b1110000000000011, &this_class::__c_lwsp},
/* instruction C.MV */
{16, 0b1000000000000010, 0b1111000000000011, &this_class::__c_mv},
/* instruction C.JR */
{16, 0b1000000000000010, 0b1111000001111111, &this_class::__c_jr},
/* instruction C.ADD */
{16, 0b1001000000000010, 0b1111000000000011, &this_class::__c_add},
/* instruction C.JALR */
{16, 0b1001000000000010, 0b1111000001111111, &this_class::__c_jalr},
/* instruction C.EBREAK */
{16, 0b1001000000000010, 0b1111111111111111, &this_class::__c_ebreak},
/* instruction C.SWSP */
{16, 0b1100000000000010, 0b1110000000000011, &this_class::__c_swsp},
/* instruction DII */
{16, 0b0000000000000000, 0b1111111111111111, &this_class::__dii},
/* instruction LR.W */
{32, 0b00010000000000000010000000101111, 0b11111001111100000111000001111111, &this_class::__lr_w},
/* instruction SC.W */
{32, 0b00011000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__sc_w},
/* instruction AMOSWAP.W */
{32, 0b00001000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__amoswap_w},
/* instruction AMOADD.W */
{32, 0b00000000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__amoadd_w},
/* instruction AMOXOR.W */
{32, 0b00100000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__amoxor_w},
/* instruction AMOAND.W */
{32, 0b01100000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__amoand_w},
/* instruction AMOOR.W */
{32, 0b01000000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__amoor_w},
/* instruction AMOMIN.W */
{32, 0b10000000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__amomin_w},
/* instruction AMOMAX.W */
{32, 0b10100000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__amomax_w},
/* instruction AMOMINU.W */
{32, 0b11000000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__amominu_w},
/* instruction AMOMAXU.W */
{32, 0b11100000000000000010000000101111, 0b11111000000000000111000001111111, &this_class::__amomaxu_w},
/* instruction MUL */
{32, 0b00000010000000000000000000110011, 0b11111110000000000111000001111111, &this_class::__mul},
/* instruction MULH */
{32, 0b00000010000000000001000000110011, 0b11111110000000000111000001111111, &this_class::__mulh},
/* instruction MULHSU */
{32, 0b00000010000000000010000000110011, 0b11111110000000000111000001111111, &this_class::__mulhsu},
/* instruction MULHU */
{32, 0b00000010000000000011000000110011, 0b11111110000000000111000001111111, &this_class::__mulhu},
/* instruction DIV */
{32, 0b00000010000000000100000000110011, 0b11111110000000000111000001111111, &this_class::__div},
/* instruction DIVU */
{32, 0b00000010000000000101000000110011, 0b11111110000000000111000001111111, &this_class::__divu},
/* instruction REM */
{32, 0b00000010000000000110000000110011, 0b11111110000000000111000001111111, &this_class::__rem},
/* instruction REMU */
{32, 0b00000010000000000111000000110011, 0b11111110000000000111000001111111, &this_class::__remu},
/* instruction LUI */
{32, 0b00000000000000000000000000110111, 0b00000000000000000000000001111111, &this_class::__lui},
/* instruction AUIPC */
{32, 0b00000000000000000000000000010111, 0b00000000000000000000000001111111, &this_class::__auipc},
/* instruction JAL */
{32, 0b00000000000000000000000001101111, 0b00000000000000000000000001111111, &this_class::__jal},
/* instruction BEQ */
{32, 0b00000000000000000000000001100011, 0b00000000000000000111000001111111, &this_class::__beq},
/* instruction BNE */
{32, 0b00000000000000000001000001100011, 0b00000000000000000111000001111111, &this_class::__bne},
/* instruction BLT */
{32, 0b00000000000000000100000001100011, 0b00000000000000000111000001111111, &this_class::__blt},
/* instruction BGE */
{32, 0b00000000000000000101000001100011, 0b00000000000000000111000001111111, &this_class::__bge},
/* instruction BLTU */
{32, 0b00000000000000000110000001100011, 0b00000000000000000111000001111111, &this_class::__bltu},
/* instruction BGEU */
{32, 0b00000000000000000111000001100011, 0b00000000000000000111000001111111, &this_class::__bgeu},
/* instruction LB */
{32, 0b00000000000000000000000000000011, 0b00000000000000000111000001111111, &this_class::__lb},
/* instruction LH */
{32, 0b00000000000000000001000000000011, 0b00000000000000000111000001111111, &this_class::__lh},
/* instruction LW */
{32, 0b00000000000000000010000000000011, 0b00000000000000000111000001111111, &this_class::__lw},
/* instruction LBU */
{32, 0b00000000000000000100000000000011, 0b00000000000000000111000001111111, &this_class::__lbu},
/* instruction LHU */
{32, 0b00000000000000000101000000000011, 0b00000000000000000111000001111111, &this_class::__lhu},
/* instruction SB */
{32, 0b00000000000000000000000000100011, 0b00000000000000000111000001111111, &this_class::__sb},
/* instruction SH */
{32, 0b00000000000000000001000000100011, 0b00000000000000000111000001111111, &this_class::__sh},
/* instruction SW */
{32, 0b00000000000000000010000000100011, 0b00000000000000000111000001111111, &this_class::__sw},
/* instruction ADDI */
{32, 0b00000000000000000000000000010011, 0b00000000000000000111000001111111, &this_class::__addi},
/* instruction SLTI */
{32, 0b00000000000000000010000000010011, 0b00000000000000000111000001111111, &this_class::__slti},
/* instruction SLTIU */
{32, 0b00000000000000000011000000010011, 0b00000000000000000111000001111111, &this_class::__sltiu},
/* instruction XORI */
{32, 0b00000000000000000100000000010011, 0b00000000000000000111000001111111, &this_class::__xori},
/* instruction ORI */
{32, 0b00000000000000000110000000010011, 0b00000000000000000111000001111111, &this_class::__ori},
/* instruction ANDI */
{32, 0b00000000000000000111000000010011, 0b00000000000000000111000001111111, &this_class::__andi},
/* instruction SLLI */
{32, 0b00000000000000000001000000010011, 0b11111110000000000111000001111111, &this_class::__slli},
/* instruction SRLI */
{32, 0b00000000000000000101000000010011, 0b11111110000000000111000001111111, &this_class::__srli},
/* instruction SRAI */
{32, 0b01000000000000000101000000010011, 0b11111110000000000111000001111111, &this_class::__srai},
/* instruction ADD */
{32, 0b00000000000000000000000000110011, 0b11111110000000000111000001111111, &this_class::__add},
/* instruction SUB */
{32, 0b01000000000000000000000000110011, 0b11111110000000000111000001111111, &this_class::__sub},
/* instruction SLL */
{32, 0b00000000000000000001000000110011, 0b11111110000000000111000001111111, &this_class::__sll},
/* instruction SLT */
{32, 0b00000000000000000010000000110011, 0b11111110000000000111000001111111, &this_class::__slt},
/* instruction SLTU */
{32, 0b00000000000000000011000000110011, 0b11111110000000000111000001111111, &this_class::__sltu},
/* instruction XOR */
{32, 0b00000000000000000100000000110011, 0b11111110000000000111000001111111, &this_class::__xor},
/* instruction SRL */
{32, 0b00000000000000000101000000110011, 0b11111110000000000111000001111111, &this_class::__srl},
/* instruction SRA */
{32, 0b01000000000000000101000000110011, 0b11111110000000000111000001111111, &this_class::__sra},
/* instruction OR */
{32, 0b00000000000000000110000000110011, 0b11111110000000000111000001111111, &this_class::__or},
/* instruction AND */
{32, 0b00000000000000000111000000110011, 0b11111110000000000111000001111111, &this_class::__and},
/* instruction FENCE */
{32, 0b00000000000000000000000000001111, 0b11110000000000000111000001111111, &this_class::__fence},
/* instruction FENCE_I */
{32, 0b00000000000000000001000000001111, 0b00000000000000000111000001111111, &this_class::__fence_i},
/* instruction ECALL */
{32, 0b00000000000000000000000001110011, 0b11111111111111111111111111111111, &this_class::__ecall},
/* instruction EBREAK */
{32, 0b00000000000100000000000001110011, 0b11111111111111111111111111111111, &this_class::__ebreak},
/* instruction URET */
{32, 0b00000000001000000000000001110011, 0b11111111111111111111111111111111, &this_class::__uret},
/* instruction SRET */
{32, 0b00010000001000000000000001110011, 0b11111111111111111111111111111111, &this_class::__sret},
/* instruction MRET */
{32, 0b00110000001000000000000001110011, 0b11111111111111111111111111111111, &this_class::__mret},
/* instruction WFI */
{32, 0b00010000010100000000000001110011, 0b11111111111111111111111111111111, &this_class::__wfi},
/* instruction SFENCE.VMA */
{32, 0b00010010000000000000000001110011, 0b11111110000000000111111111111111, &this_class::__sfence_vma},
/* instruction CSRRW */
{32, 0b00000000000000000001000001110011, 0b00000000000000000111000001111111, &this_class::__csrrw},
/* instruction CSRRS */
{32, 0b00000000000000000010000001110011, 0b00000000000000000111000001111111, &this_class::__csrrs},
/* instruction CSRRC */
{32, 0b00000000000000000011000001110011, 0b00000000000000000111000001111111, &this_class::__csrrc},
/* instruction CSRRWI */
{32, 0b00000000000000000101000001110011, 0b00000000000000000111000001111111, &this_class::__csrrwi},
/* instruction CSRRSI */
{32, 0b00000000000000000110000001110011, 0b00000000000000000111000001111111, &this_class::__csrrsi},
/* instruction CSRRCI */
{32, 0b00000000000000000111000001110011, 0b00000000000000000111000001111111, &this_class::__csrrci},
}};
/* instruction definitions */
/* instruction 0: JALR */
compile_ret_t __jalr(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 1: C.ADDI4SPN */
compile_ret_t __c_addi4spn(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 2: C.LW */
compile_ret_t __c_lw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 3: C.SW */
compile_ret_t __c_sw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 4: C.ADDI */
compile_ret_t __c_addi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 5: C.NOP */
compile_ret_t __c_nop(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 6: C.JAL */
compile_ret_t __c_jal(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 7: C.LI */
compile_ret_t __c_li(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 8: C.LUI */
compile_ret_t __c_lui(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 9: C.ADDI16SP */
compile_ret_t __c_addi16sp(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 10: C.SRLI */
compile_ret_t __c_srli(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 11: C.SRAI */
compile_ret_t __c_srai(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 12: C.ANDI */
compile_ret_t __c_andi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 13: C.SUB */
compile_ret_t __c_sub(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 14: C.XOR */
compile_ret_t __c_xor(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 15: C.OR */
compile_ret_t __c_or(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 16: C.AND */
compile_ret_t __c_and(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 17: C.J */
compile_ret_t __c_j(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 18: C.BEQZ */
compile_ret_t __c_beqz(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 19: C.BNEZ */
compile_ret_t __c_bnez(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 20: C.SLLI */
compile_ret_t __c_slli(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 21: C.LWSP */
compile_ret_t __c_lwsp(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 22: C.MV */
compile_ret_t __c_mv(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 23: C.JR */
compile_ret_t __c_jr(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 24: C.ADD */
compile_ret_t __c_add(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 25: C.JALR */
compile_ret_t __c_jalr(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 26: C.EBREAK */
compile_ret_t __c_ebreak(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 27: C.SWSP */
compile_ret_t __c_swsp(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 28: DII */
compile_ret_t __dii(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 29: LR.W */
compile_ret_t __lr_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 30: SC.W */
compile_ret_t __sc_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 31: AMOSWAP.W */
compile_ret_t __amoswap_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 32: AMOADD.W */
compile_ret_t __amoadd_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 33: AMOXOR.W */
compile_ret_t __amoxor_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 34: AMOAND.W */
compile_ret_t __amoand_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 35: AMOOR.W */
compile_ret_t __amoor_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 36: AMOMIN.W */
compile_ret_t __amomin_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 37: AMOMAX.W */
compile_ret_t __amomax_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 38: AMOMINU.W */
compile_ret_t __amominu_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 39: AMOMAXU.W */
compile_ret_t __amomaxu_w(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 40: MUL */
compile_ret_t __mul(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 41: MULH */
compile_ret_t __mulh(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 42: MULHSU */
compile_ret_t __mulhsu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 43: MULHU */
compile_ret_t __mulhu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 44: DIV */
compile_ret_t __div(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 45: DIVU */
compile_ret_t __divu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 46: REM */
compile_ret_t __rem(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 47: REMU */
compile_ret_t __remu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 48: LUI */
compile_ret_t __lui(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 49: AUIPC */
compile_ret_t __auipc(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 50: JAL */
compile_ret_t __jal(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 51: BEQ */
compile_ret_t __beq(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 52: BNE */
compile_ret_t __bne(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 53: BLT */
compile_ret_t __blt(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 54: BGE */
compile_ret_t __bge(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 55: BLTU */
compile_ret_t __bltu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 56: BGEU */
compile_ret_t __bgeu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 57: LB */
compile_ret_t __lb(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 58: LH */
compile_ret_t __lh(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 59: LW */
compile_ret_t __lw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 60: LBU */
compile_ret_t __lbu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 61: LHU */
compile_ret_t __lhu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 62: SB */
compile_ret_t __sb(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 63: SH */
compile_ret_t __sh(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 64: SW */
compile_ret_t __sw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 65: ADDI */
compile_ret_t __addi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 66: SLTI */
compile_ret_t __slti(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 67: SLTIU */
compile_ret_t __sltiu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 68: XORI */
compile_ret_t __xori(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 69: ORI */
compile_ret_t __ori(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 70: ANDI */
compile_ret_t __andi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 71: SLLI */
compile_ret_t __slli(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 72: SRLI */
compile_ret_t __srli(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 73: SRAI */
compile_ret_t __srai(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 74: ADD */
compile_ret_t __add(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 75: SUB */
compile_ret_t __sub(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 76: SLL */
compile_ret_t __sll(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 77: SLT */
compile_ret_t __slt(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 78: SLTU */
compile_ret_t __sltu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 79: XOR */
compile_ret_t __xor(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 80: SRL */
compile_ret_t __srl(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 81: SRA */
compile_ret_t __sra(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 82: OR */
compile_ret_t __or(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 83: AND */
compile_ret_t __and(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 84: FENCE */
compile_ret_t __fence(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 85: FENCE_I */
compile_ret_t __fence_i(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 86: ECALL */
compile_ret_t __ecall(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 87: EBREAK */
compile_ret_t __ebreak(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 88: URET */
compile_ret_t __uret(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 89: SRET */
compile_ret_t __sret(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 90: MRET */
compile_ret_t __mret(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 91: WFI */
compile_ret_t __wfi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 92: SFENCE.VMA */
compile_ret_t __sfence_vma(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 93: CSRRW */
compile_ret_t __csrrw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 94: CSRRS */
compile_ret_t __csrrs(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 95: CSRRC */
compile_ret_t __csrrc(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 96: CSRRWI */
compile_ret_t __csrrwi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 97: CSRRSI */
compile_ret_t __csrrsi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 98: CSRRCI */
compile_ret_t __csrrci(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/****************************************************************************
* end opcode definitions
****************************************************************************/
compile_ret_t illegal_intruction(virt_addr_t &pc, code_word_t instr, std::stringstream& os) {
this->gen_sync(iss::PRE_SYNC, instr_descr.size());
this->builder.CreateStore(this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::NEXT_PC), true),
get_reg_ptr(traits<ARCH>::PC), true);
this->builder.CreateStore(
this->builder.CreateAdd(this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::ICOUNT), true),
this->gen_const(64U, 1)),
get_reg_ptr(traits<ARCH>::ICOUNT), true);
pc = pc + ((instr & 3) == 3 ? 4 : 2);
this->gen_raise_trap(0, 2); // illegal instruction trap
this->gen_sync(iss::POST_SYNC, instr_descr.size());
this->gen_trap_check(this->leave_blk);
return BRANCH;
}
};
template <typename CODE_WORD> void debug_fn(CODE_WORD insn) {
volatile CODE_WORD x = insn;
insn = 2 * x;
}
template <typename ARCH> vm_impl<ARCH>::vm_impl() { this(new ARCH()); }
template <typename ARCH>
vm_impl<ARCH>::vm_impl(ARCH &core, unsigned core_id, unsigned cluster_id)
: vm_base<ARCH>(core, core_id, cluster_id) {
qlut[0] = lut_00.data();
qlut[1] = lut_01.data();
qlut[2] = lut_10.data();
qlut[3] = lut_11.data();
for (auto instr : instr_descr) {
auto quantrant = instr.value & 0x3;
expand_bit_mask(29, lutmasks[quantrant], instr.value >> 2, instr.mask >> 2, 0, qlut[quantrant], instr.op);
}
}
template <typename ARCH>
std::tuple<continuation_e>
vm_impl<ARCH>::gen_single_inst_behavior(virt_addr_t &pc, unsigned int &inst_cnt, std::ostringstrem& os) {
// we fetch at max 4 byte, alignment is 2
enum {TRAP_ID=1<<16};
code_word_t insn = 0;
const typename traits<ARCH>::addr_t upper_bits = ~traits<ARCH>::PGMASK;
phys_addr_t paddr(pc);
auto *const data = (uint8_t *)&insn;
paddr = this->core.v2p(pc);
if ((pc.val & upper_bits) != ((pc.val + 2) & upper_bits)) { // we may cross a page boundary
auto res = this->core.read(paddr, 2, data);
if (res != iss::Ok) throw trap_access(TRAP_ID, pc.val);
if ((insn & 0x3) == 0x3) { // this is a 32bit instruction
res = this->core.read(this->core.v2p(pc + 2), 2, data + 2);
}
} else {
auto res = this->core.read(paddr, 4, data);
if (res != iss::Ok) throw trap_access(TRAP_ID, pc.val);
}
if (insn == 0x0000006f || (insn&0xffff)==0xa001) throw simulation_stopped(0); // 'J 0' or 'C.J 0'
// curr pc on stack
++inst_cnt;
auto lut_val = extract_fields(insn);
auto f = qlut[insn & 0x3][lut_val];
if (f == nullptr) {
f = &this_class::illegal_intruction;
}
return (this->*f)(pc, insn, this_block);
}
template <typename ARCH> void vm_impl<ARCH>::gen_leave_behavior(BasicBlock *leave_blk) {
this->builder.SetInsertPoint(leave_blk);
this->builder.CreateRet(this->builder.CreateLoad(get_reg_ptr(arch::traits<ARCH>::NEXT_PC), false));
}
template <typename ARCH> void vm_impl<ARCH>::gen_raise_trap(uint16_t trap_id, uint16_t cause) {
auto *TRAP_val = this->gen_const(32, 0x80 << 24 | (cause << 16) | trap_id);
this->builder.CreateStore(TRAP_val, get_reg_ptr(traits<ARCH>::TRAP_STATE), true);
this->builder.CreateStore(this->gen_const(32U, std::numeric_limits<uint32_t>::max()), get_reg_ptr(traits<ARCH>::LAST_BRANCH), false);
}
template <typename ARCH> void vm_impl<ARCH>::gen_leave_trap(unsigned lvl) {
std::vector<Value *> args{ this->core_ptr, ConstantInt::get(getContext(), APInt(64, lvl)) };
this->builder.CreateCall(this->mod->getFunction("leave_trap"), args);
auto *PC_val = this->gen_read_mem(traits<ARCH>::CSR, (lvl << 8) + 0x41, traits<ARCH>::XLEN / 8);
this->builder.CreateStore(PC_val, get_reg_ptr(traits<ARCH>::NEXT_PC), false);
this->builder.CreateStore(this->gen_const(32U, std::numeric_limits<uint32_t>::max()), get_reg_ptr(traits<ARCH>::LAST_BRANCH), false);
}
template <typename ARCH> void vm_impl<ARCH>::gen_wait(unsigned type) {
std::vector<Value *> args{ this->core_ptr, ConstantInt::get(getContext(), APInt(64, type)) };
this->builder.CreateCall(this->mod->getFunction("wait"), args);
}
template <typename ARCH> void vm_impl<ARCH>::gen_trap_behavior(BasicBlock *trap_blk) {
this->builder.SetInsertPoint(trap_blk);
auto *trap_state_val = this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::TRAP_STATE), true);
this->builder.CreateStore(this->gen_const(32U, std::numeric_limits<uint32_t>::max()),
get_reg_ptr(traits<ARCH>::LAST_BRANCH), false);
std::vector<Value *> args{this->core_ptr, this->adj_to64(trap_state_val),
this->adj_to64(this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::PC), false))};
this->builder.CreateCall(this->mod->getFunction("enter_trap"), args);
auto *trap_addr_val = this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::NEXT_PC), false);
this->builder.CreateRet(trap_addr_val);
}
template <typename ARCH> inline void vm_impl<ARCH>::gen_trap_check(BasicBlock *bb) {
auto *v = this->builder.CreateLoad(get_reg_ptr(arch::traits<ARCH>::TRAP_STATE), true);
this->gen_cond_branch(this->builder.CreateICmp(
ICmpInst::ICMP_EQ, v,
ConstantInt::get(getContext(), APInt(v->getType()->getIntegerBitWidth(), 0))),
bb, this->trap_blk, 1);
}
} // namespace rv32imac
template <>
std::unique_ptr<vm_if> create<arch::rv32imac>(arch::rv32imac *core, unsigned short port, bool dump) {
auto ret = new rv32imac::vm_impl<arch::rv32imac>(*core, dump);
if (port != 0) debugger::server<debugger::gdb_session>::run_server(ret, port);
return std::unique_ptr<vm_if>(ret);
}
}
} // namespace iss

1543
src/vm/tcc/vm_rv64gc.cpp
View File

File diff suppressed because it is too large Load Diff

724
src/vm/tcc/vm_rv64i.cpp
View File

@@ -1,724 +0,0 @@
/*******************************************************************************
* Copyright (C) 2020 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
*******************************************************************************/
#include <iss/arch/rv64i.h>
#include <iss/arch/riscv_hart_msu_vp.h>
#include <iss/debugger/gdb_session.h>
#include <iss/debugger/server.h>
#include <iss/iss.h>
#include <iss/tcc/vm_base.h>
#include <util/logging.h>
#ifndef FMT_HEADER_ONLY
#define FMT_HEADER_ONLY
#endif
#include <fmt/format.h>
#include <array>
#include <iss/debugger/riscv_target_adapter.h>
namespace iss {
namespace vm {
namespace fp_impl {
void add_fp_functions_2_module(llvm::Module *, unsigned, unsigned);
}
}
namespace tcc {
namespace rv64i {
using namespace iss::arch;
using namespace iss::debugger;
template <typename ARCH> class vm_impl : public vm_base<ARCH> {
public:
using super = typename iss::tcc::vm_base<ARCH>;
using virt_addr_t = typename super::virt_addr_t;
using phys_addr_t = typename super::phys_addr_t;
using code_word_t = typename super::code_word_t;
using addr_t = typename super::addr_t;
vm_impl();
vm_impl(ARCH &core, unsigned core_id = 0, unsigned cluster_id = 0);
void enableDebug(bool enable) { super::sync_exec = super::ALL_SYNC; }
target_adapter_if *accquire_target_adapter(server_if *srv) override {
debugger_if::dbg_enabled = true;
if (vm_base<ARCH>::tgt_adapter == nullptr)
vm_base<ARCH>::tgt_adapter = new riscv_target_adapter<ARCH>(srv, this->get_arch());
return vm_base<ARCH>::tgt_adapter;
}
protected:
using vm_base<ARCH>::get_reg_ptr;
using this_class = vm_impl<ARCH>;
using compile_ret_t = std::tuple<continuation_e>;
using compile_func = compile_ret_t (this_class::*)(virt_addr_t &pc, code_word_t instr, std::ostringstream&);
inline const char *name(size_t index){return traits<ARCH>::reg_aliases.at(index);}
template <typename T> inline ConstantInt *size(T type) {
return ConstantInt::get(getContext(), APInt(32, type->getType()->getScalarSizeInBits()));
}
void setup_module(Module* m) override {
super::setup_module(m);
iss::vm::fp_impl::add_fp_functions_2_module(m, traits<ARCH>::FP_REGS_SIZE, traits<ARCH>::XLEN);
}
inline Value *gen_choose(Value *cond, Value *trueVal, Value *falseVal, unsigned size) {
return super::gen_cond_assign(cond, this->gen_ext(trueVal, size), this->gen_ext(falseVal, size));
}
compile_ret_t gen_single_inst_behavior(virt_addr_t &, unsigned int &, std::ostringstream&) override;
void gen_leave_behavior(BasicBlock *leave_blk) override;
void gen_raise_trap(uint16_t trap_id, uint16_t cause);
void gen_leave_trap(unsigned lvl);
void gen_wait(unsigned type);
void gen_trap_behavior(BasicBlock *) override;
std::string gen_trap_check(BasicBlock *bb);
inline Value *gen_reg_load(unsigned i, unsigned level = 0) {
return this->builder.CreateLoad(get_reg_ptr(i), false);
}
inline std::string gen_set_pc(virt_addr_t pc, unsigned reg_num) {
return fmt::format("*((uint64_t*){}) = {}\n", get_reg_ptr(reg_num), next_pc_v.val);
}
// some compile time constants
// enum { MASK16 = 0b1111110001100011, MASK32 = 0b11111111111100000111000001111111 };
enum { MASK16 = 0b1111111111111111, MASK32 = 0b11111111111100000111000001111111 };
enum { EXTR_MASK16 = MASK16 >> 2, EXTR_MASK32 = MASK32 >> 2 };
enum { LUT_SIZE = 1 << util::bit_count(EXTR_MASK32), LUT_SIZE_C = 1 << util::bit_count(EXTR_MASK16) };
std::array<compile_func, LUT_SIZE> lut;
std::array<compile_func, LUT_SIZE_C> lut_00, lut_01, lut_10;
std::array<compile_func, LUT_SIZE> lut_11;
std::array<compile_func *, 4> qlut;
std::array<const uint32_t, 4> lutmasks = {{EXTR_MASK16, EXTR_MASK16, EXTR_MASK16, EXTR_MASK32}};
void expand_bit_mask(int pos, uint32_t mask, uint32_t value, uint32_t valid, uint32_t idx, compile_func lut[],
compile_func f) {
if (pos < 0) {
lut[idx] = f;
} else {
auto bitmask = 1UL << pos;
if ((mask & bitmask) == 0) {
expand_bit_mask(pos - 1, mask, value, valid, idx, lut, f);
} else {
if ((valid & bitmask) == 0) {
expand_bit_mask(pos - 1, mask, value, valid, (idx << 1), lut, f);
expand_bit_mask(pos - 1, mask, value, valid, (idx << 1) + 1, lut, f);
} else {
auto new_val = idx << 1;
if ((value & bitmask) != 0) new_val++;
expand_bit_mask(pos - 1, mask, value, valid, new_val, lut, f);
}
}
}
}
inline uint32_t extract_fields(uint32_t val) { return extract_fields(29, val >> 2, lutmasks[val & 0x3], 0); }
uint32_t extract_fields(int pos, uint32_t val, uint32_t mask, uint32_t lut_val) {
if (pos >= 0) {
auto bitmask = 1UL << pos;
if ((mask & bitmask) == 0) {
lut_val = extract_fields(pos - 1, val, mask, lut_val);
} else {
auto new_val = lut_val << 1;
if ((val & bitmask) != 0) new_val++;
lut_val = extract_fields(pos - 1, val, mask, new_val);
}
}
return lut_val;
}
private:
/****************************************************************************
* start opcode definitions
****************************************************************************/
struct InstructionDesriptor {
size_t length;
uint32_t value;
uint32_t mask;
compile_func op;
};
const std::array<InstructionDesriptor, 64> instr_descr = {{
/* entries are: size, valid value, valid mask, function ptr */
/* instruction LUI */
{32, 0b00000000000000000000000000110111, 0b00000000000000000000000001111111, &this_class::__lui},
/* instruction AUIPC */
{32, 0b00000000000000000000000000010111, 0b00000000000000000000000001111111, &this_class::__auipc},
/* instruction JAL */
{32, 0b00000000000000000000000001101111, 0b00000000000000000000000001111111, &this_class::__jal},
/* instruction JALR */
{32, 0b00000000000000000000000001100111, 0b00000000000000000111000001111111, &this_class::__jalr},
/* instruction BEQ */
{32, 0b00000000000000000000000001100011, 0b00000000000000000111000001111111, &this_class::__beq},
/* instruction BNE */
{32, 0b00000000000000000001000001100011, 0b00000000000000000111000001111111, &this_class::__bne},
/* instruction BLT */
{32, 0b00000000000000000100000001100011, 0b00000000000000000111000001111111, &this_class::__blt},
/* instruction BGE */
{32, 0b00000000000000000101000001100011, 0b00000000000000000111000001111111, &this_class::__bge},
/* instruction BLTU */
{32, 0b00000000000000000110000001100011, 0b00000000000000000111000001111111, &this_class::__bltu},
/* instruction BGEU */
{32, 0b00000000000000000111000001100011, 0b00000000000000000111000001111111, &this_class::__bgeu},
/* instruction LB */
{32, 0b00000000000000000000000000000011, 0b00000000000000000111000001111111, &this_class::__lb},
/* instruction LH */
{32, 0b00000000000000000001000000000011, 0b00000000000000000111000001111111, &this_class::__lh},
/* instruction LW */
{32, 0b00000000000000000010000000000011, 0b00000000000000000111000001111111, &this_class::__lw},
/* instruction LBU */
{32, 0b00000000000000000100000000000011, 0b00000000000000000111000001111111, &this_class::__lbu},
/* instruction LHU */
{32, 0b00000000000000000101000000000011, 0b00000000000000000111000001111111, &this_class::__lhu},
/* instruction SB */
{32, 0b00000000000000000000000000100011, 0b00000000000000000111000001111111, &this_class::__sb},
/* instruction SH */
{32, 0b00000000000000000001000000100011, 0b00000000000000000111000001111111, &this_class::__sh},
/* instruction SW */
{32, 0b00000000000000000010000000100011, 0b00000000000000000111000001111111, &this_class::__sw},
/* instruction ADDI */
{32, 0b00000000000000000000000000010011, 0b00000000000000000111000001111111, &this_class::__addi},
/* instruction SLTI */
{32, 0b00000000000000000010000000010011, 0b00000000000000000111000001111111, &this_class::__slti},
/* instruction SLTIU */
{32, 0b00000000000000000011000000010011, 0b00000000000000000111000001111111, &this_class::__sltiu},
/* instruction XORI */
{32, 0b00000000000000000100000000010011, 0b00000000000000000111000001111111, &this_class::__xori},
/* instruction ORI */
{32, 0b00000000000000000110000000010011, 0b00000000000000000111000001111111, &this_class::__ori},
/* instruction ANDI */
{32, 0b00000000000000000111000000010011, 0b00000000000000000111000001111111, &this_class::__andi},
/* instruction SLLI */
{32, 0b00000000000000000001000000010011, 0b11111100000000000111000001111111, &this_class::__slli},
/* instruction SRLI */
{32, 0b00000000000000000101000000010011, 0b11111100000000000111000001111111, &this_class::__srli},
/* instruction SRAI */
{32, 0b01000000000000000101000000010011, 0b11111100000000000111000001111111, &this_class::__srai},
/* instruction ADD */
{32, 0b00000000000000000000000000110011, 0b11111110000000000111000001111111, &this_class::__add},
/* instruction SUB */
{32, 0b01000000000000000000000000110011, 0b11111110000000000111000001111111, &this_class::__sub},
/* instruction SLL */
{32, 0b00000000000000000001000000110011, 0b11111110000000000111000001111111, &this_class::__sll},
/* instruction SLT */
{32, 0b00000000000000000010000000110011, 0b11111110000000000111000001111111, &this_class::__slt},
/* instruction SLTU */
{32, 0b00000000000000000011000000110011, 0b11111110000000000111000001111111, &this_class::__sltu},
/* instruction XOR */
{32, 0b00000000000000000100000000110011, 0b11111110000000000111000001111111, &this_class::__xor},
/* instruction SRL */
{32, 0b00000000000000000101000000110011, 0b11111110000000000111000001111111, &this_class::__srl},
/* instruction SRA */
{32, 0b01000000000000000101000000110011, 0b11111110000000000111000001111111, &this_class::__sra},
/* instruction OR */
{32, 0b00000000000000000110000000110011, 0b11111110000000000111000001111111, &this_class::__or},
/* instruction AND */
{32, 0b00000000000000000111000000110011, 0b11111110000000000111000001111111, &this_class::__and},
/* instruction FENCE */
{32, 0b00000000000000000000000000001111, 0b11110000000000000111000001111111, &this_class::__fence},
/* instruction FENCE_I */
{32, 0b00000000000000000001000000001111, 0b00000000000000000111000001111111, &this_class::__fence_i},
/* instruction ECALL */
{32, 0b00000000000000000000000001110011, 0b11111111111111111111111111111111, &this_class::__ecall},
/* instruction EBREAK */
{32, 0b00000000000100000000000001110011, 0b11111111111111111111111111111111, &this_class::__ebreak},
/* instruction URET */
{32, 0b00000000001000000000000001110011, 0b11111111111111111111111111111111, &this_class::__uret},
/* instruction SRET */
{32, 0b00010000001000000000000001110011, 0b11111111111111111111111111111111, &this_class::__sret},
/* instruction MRET */
{32, 0b00110000001000000000000001110011, 0b11111111111111111111111111111111, &this_class::__mret},
/* instruction WFI */
{32, 0b00010000010100000000000001110011, 0b11111111111111111111111111111111, &this_class::__wfi},
/* instruction SFENCE.VMA */
{32, 0b00010010000000000000000001110011, 0b11111110000000000111111111111111, &this_class::__sfence_vma},
/* instruction CSRRW */
{32, 0b00000000000000000001000001110011, 0b00000000000000000111000001111111, &this_class::__csrrw},
/* instruction CSRRS */
{32, 0b00000000000000000010000001110011, 0b00000000000000000111000001111111, &this_class::__csrrs},
/* instruction CSRRC */
{32, 0b00000000000000000011000001110011, 0b00000000000000000111000001111111, &this_class::__csrrc},
/* instruction CSRRWI */
{32, 0b00000000000000000101000001110011, 0b00000000000000000111000001111111, &this_class::__csrrwi},
/* instruction CSRRSI */
{32, 0b00000000000000000110000001110011, 0b00000000000000000111000001111111, &this_class::__csrrsi},
/* instruction CSRRCI */
{32, 0b00000000000000000111000001110011, 0b00000000000000000111000001111111, &this_class::__csrrci},
/* instruction LWU */
{32, 0b00000000000000000110000000000011, 0b00000000000000000111000001111111, &this_class::__lwu},
/* instruction LD */
{32, 0b00000000000000000011000000000011, 0b00000000000000000111000001111111, &this_class::__ld},
/* instruction SD */
{32, 0b00000000000000000011000000100011, 0b00000000000000000111000001111111, &this_class::__sd},
/* instruction ADDIW */
{32, 0b00000000000000000000000000011011, 0b00000000000000000111000001111111, &this_class::__addiw},
/* instruction SLLIW */
{32, 0b00000000000000000001000000011011, 0b11111110000000000111000001111111, &this_class::__slliw},
/* instruction SRLIW */
{32, 0b00000000000000000101000000011011, 0b11111110000000000111000001111111, &this_class::__srliw},
/* instruction SRAIW */
{32, 0b01000000000000000101000000011011, 0b11111110000000000111000001111111, &this_class::__sraiw},
/* instruction ADDW */
{32, 0b00000000000000000000000000111011, 0b11111110000000000111000001111111, &this_class::__addw},
/* instruction SUBW */
{32, 0b01000000000000000000000000111011, 0b11111110000000000111000001111111, &this_class::__subw},
/* instruction SLLW */
{32, 0b00000000000000000001000000111011, 0b11111110000000000111000001111111, &this_class::__sllw},
/* instruction SRLW */
{32, 0b00000000000000000101000000111011, 0b11111110000000000111000001111111, &this_class::__srlw},
/* instruction SRAW */
{32, 0b01000000000000000101000000111011, 0b11111110000000000111000001111111, &this_class::__sraw},
}};
/* instruction definitions */
/* instruction 0: LUI */
compile_ret_t __lui(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 1: AUIPC */
compile_ret_t __auipc(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
os<<fmt::format("AUIPC-{:%08x}:\n", pc.val);
os<<this->gen_sync(PRE_SYNC, 1);
uint8_t rd = ((bit_sub<7,5>(instr)));
int32_t imm = signextend<int32_t,32>((bit_sub<12,20>(instr) << 12));
if(this->disass_enabled){
/* generate console output when executing the command */
auto mnemonic = fmt::format(
"{mnemonic:10} {rd}, {imm:#08x}", fmt::arg("mnemonic", "auipc"),
fmt::arg("rd", name(rd)), fmt::arg("imm", imm));
this->builder.CreateCall(this->mod->getFunction("print_disass"), args);
os<<fmt::format("\tprint_disass((void*){}, {}, {});\n", this->core_ptr, pc.val, mnemonic);
}
Value* cur_pc_val = this->gen_const(64, pc.val);
pc=pc+4;
if(rd != 0){
os<<fmt::format("uint64_t res = {} + {};\n", cur_pc_val, imm);
os<<fmt::format("*((uint64_t*){}) = ret\n", get_reg_ptr(rd + traits<ARCH>::X0));
}
os<<this->gen_set_pc(pc, traits<ARCH>::NEXT_PC);
os<<this->gen_sync(POST_SYNC, 1);
os<<this->gen_trap_check(bb);
return std::make_tuple(CONT);
}
/* instruction 2: JAL */
compile_ret_t __jal(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 3: JALR */
compile_ret_t __jalr(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 4: BEQ */
compile_ret_t __beq(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 5: BNE */
compile_ret_t __bne(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 6: BLT */
compile_ret_t __blt(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 7: BGE */
compile_ret_t __bge(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 8: BLTU */
compile_ret_t __bltu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 9: BGEU */
compile_ret_t __bgeu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 10: LB */
compile_ret_t __lb(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 11: LH */
compile_ret_t __lh(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 12: LW */
compile_ret_t __lw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 13: LBU */
compile_ret_t __lbu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 14: LHU */
compile_ret_t __lhu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 15: SB */
compile_ret_t __sb(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 16: SH */
compile_ret_t __sh(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 17: SW */
compile_ret_t __sw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 18: ADDI */
compile_ret_t __addi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 19: SLTI */
compile_ret_t __slti(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 20: SLTIU */
compile_ret_t __sltiu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 21: XORI */
compile_ret_t __xori(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 22: ORI */
compile_ret_t __ori(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 23: ANDI */
compile_ret_t __andi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 24: SLLI */
compile_ret_t __slli(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 25: SRLI */
compile_ret_t __srli(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 26: SRAI */
compile_ret_t __srai(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 27: ADD */
compile_ret_t __add(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 28: SUB */
compile_ret_t __sub(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 29: SLL */
compile_ret_t __sll(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 30: SLT */
compile_ret_t __slt(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 31: SLTU */
compile_ret_t __sltu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 32: XOR */
compile_ret_t __xor(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 33: SRL */
compile_ret_t __srl(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 34: SRA */
compile_ret_t __sra(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 35: OR */
compile_ret_t __or(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 36: AND */
compile_ret_t __and(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 37: FENCE */
compile_ret_t __fence(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 38: FENCE_I */
compile_ret_t __fence_i(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 39: ECALL */
compile_ret_t __ecall(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 40: EBREAK */
compile_ret_t __ebreak(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 41: URET */
compile_ret_t __uret(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 42: SRET */
compile_ret_t __sret(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 43: MRET */
compile_ret_t __mret(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 44: WFI */
compile_ret_t __wfi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 45: SFENCE.VMA */
compile_ret_t __sfence_vma(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 46: CSRRW */
compile_ret_t __csrrw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 47: CSRRS */
compile_ret_t __csrrs(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 48: CSRRC */
compile_ret_t __csrrc(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 49: CSRRWI */
compile_ret_t __csrrwi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 50: CSRRSI */
compile_ret_t __csrrsi(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 51: CSRRCI */
compile_ret_t __csrrci(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 52: LWU */
compile_ret_t __lwu(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 53: LD */
compile_ret_t __ld(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 54: SD */
compile_ret_t __sd(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 55: ADDIW */
compile_ret_t __addiw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 56: SLLIW */
compile_ret_t __slliw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 57: SRLIW */
compile_ret_t __srliw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 58: SRAIW */
compile_ret_t __sraiw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 59: ADDW */
compile_ret_t __addw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 60: SUBW */
compile_ret_t __subw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 61: SLLW */
compile_ret_t __sllw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 62: SRLW */
compile_ret_t __srlw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/* instruction 63: SRAW */
compile_ret_t __sraw(virt_addr_t& pc, code_word_t instr, std::ostringstream& os){
}
/****************************************************************************
* end opcode definitions
****************************************************************************/
compile_ret_t illegal_intruction(virt_addr_t &pc, code_word_t instr, std::stringstream& os) {
this->gen_sync(iss::PRE_SYNC, instr_descr.size());
this->builder.CreateStore(this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::NEXT_PC), true),
get_reg_ptr(traits<ARCH>::PC), true);
this->builder.CreateStore(
this->builder.CreateAdd(this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::ICOUNT), true),
this->gen_const(64U, 1)),
get_reg_ptr(traits<ARCH>::ICOUNT), true);
pc = pc + ((instr & 3) == 3 ? 4 : 2);
this->gen_raise_trap(0, 2); // illegal instruction trap
this->gen_sync(iss::POST_SYNC, instr_descr.size());
this->gen_trap_check(this->leave_blk);
return BRANCH;
}
};
template <typename CODE_WORD> void debug_fn(CODE_WORD insn) {
volatile CODE_WORD x = insn;
insn = 2 * x;
}
template <typename ARCH> vm_impl<ARCH>::vm_impl() { this(new ARCH()); }
template <typename ARCH>
vm_impl<ARCH>::vm_impl(ARCH &core, unsigned core_id, unsigned cluster_id)
: vm_base<ARCH>(core, core_id, cluster_id) {
qlut[0] = lut_00.data();
qlut[1] = lut_01.data();
qlut[2] = lut_10.data();
qlut[3] = lut_11.data();
for (auto instr : instr_descr) {
auto quantrant = instr.value & 0x3;
expand_bit_mask(29, lutmasks[quantrant], instr.value >> 2, instr.mask >> 2, 0, qlut[quantrant], instr.op);
}
}
template <typename ARCH>
std::tuple<continuation_e>
vm_impl<ARCH>::gen_single_inst_behavior(virt_addr_t &pc, unsigned int &inst_cnt, std::ostringstrem& os) {
// we fetch at max 4 byte, alignment is 2
enum {TRAP_ID=1<<16};
code_word_t insn = 0;
const typename traits<ARCH>::addr_t upper_bits = ~traits<ARCH>::PGMASK;
phys_addr_t paddr(pc);
auto *const data = (uint8_t *)&insn;
paddr = this->core.v2p(pc);
if ((pc.val & upper_bits) != ((pc.val + 2) & upper_bits)) { // we may cross a page boundary
auto res = this->core.read(paddr, 2, data);
if (res != iss::Ok) throw trap_access(TRAP_ID, pc.val);
if ((insn & 0x3) == 0x3) { // this is a 32bit instruction
res = this->core.read(this->core.v2p(pc + 2), 2, data + 2);
}
} else {
auto res = this->core.read(paddr, 4, data);
if (res != iss::Ok) throw trap_access(TRAP_ID, pc.val);
}
if (insn == 0x0000006f || (insn&0xffff)==0xa001) throw simulation_stopped(0); // 'J 0' or 'C.J 0'
// curr pc on stack
++inst_cnt;
auto lut_val = extract_fields(insn);
auto f = qlut[insn & 0x3][lut_val];
if (f == nullptr) {
f = &this_class::illegal_intruction;
}
return (this->*f)(pc, insn, this_block);
}
template <typename ARCH> void vm_impl<ARCH>::gen_leave_behavior(BasicBlock *leave_blk) {
this->builder.SetInsertPoint(leave_blk);
this->builder.CreateRet(this->builder.CreateLoad(get_reg_ptr(arch::traits<ARCH>::NEXT_PC), false));
}
template <typename ARCH> void vm_impl<ARCH>::gen_raise_trap(uint16_t trap_id, uint16_t cause) {
auto *TRAP_val = this->gen_const(32, 0x80 << 24 | (cause << 16) | trap_id);
this->builder.CreateStore(TRAP_val, get_reg_ptr(traits<ARCH>::TRAP_STATE), true);
this->builder.CreateStore(this->gen_const(32U, std::numeric_limits<uint32_t>::max()), get_reg_ptr(traits<ARCH>::LAST_BRANCH), false);
}
template <typename ARCH> void vm_impl<ARCH>::gen_leave_trap(unsigned lvl) {
std::vector<Value *> args{ this->core_ptr, ConstantInt::get(getContext(), APInt(64, lvl)) };
this->builder.CreateCall(this->mod->getFunction("leave_trap"), args);
auto *PC_val = this->gen_read_mem(traits<ARCH>::CSR, (lvl << 8) + 0x41, traits<ARCH>::XLEN / 8);
this->builder.CreateStore(PC_val, get_reg_ptr(traits<ARCH>::NEXT_PC), false);
this->builder.CreateStore(this->gen_const(32U, std::numeric_limits<uint32_t>::max()), get_reg_ptr(traits<ARCH>::LAST_BRANCH), false);
}
template <typename ARCH> void vm_impl<ARCH>::gen_wait(unsigned type) {
std::vector<Value *> args{ this->core_ptr, ConstantInt::get(getContext(), APInt(64, type)) };
this->builder.CreateCall(this->mod->getFunction("wait"), args);
}
template <typename ARCH> void vm_impl<ARCH>::gen_trap_behavior(BasicBlock *trap_blk) {
this->builder.SetInsertPoint(trap_blk);
auto *trap_state_val = this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::TRAP_STATE), true);
this->builder.CreateStore(this->gen_const(32U, std::numeric_limits<uint32_t>::max()),
get_reg_ptr(traits<ARCH>::LAST_BRANCH), false);
std::vector<Value *> args{this->core_ptr, this->adj_to64(trap_state_val),
this->adj_to64(this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::PC), false))};
this->builder.CreateCall(this->mod->getFunction("enter_trap"), args);
auto *trap_addr_val = this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::NEXT_PC), false);
this->builder.CreateRet(trap_addr_val);
}
template <typename ARCH> inline std::string vm_impl<ARCH>::gen_trap_check(BasicBlock *bb) {
return fmt::format("if(*(uint32_t){})!=0) goto trap_blk;\n", get_reg_ptr(arch::traits<ARCH>::TRAP_STATE));
}
} // namespace rv64i
template <>
std::unique_ptr<vm_if> create<arch::rv64i>(arch::rv64i *core, unsigned short port, bool dump) {
auto ret = new rv64i::vm_impl<arch::rv64i>(*core, dump);
if (port != 0) debugger::server<debugger::gdb_session>::run_server(ret, port);
return std::unique_ptr<vm_if>(ret);
}
}
} // namespace iss

2086
src/vm/tcc/vm_tgf_b.cpp Normal file
View File

File diff suppressed because it is too large Load Diff

1101
src/vm/tcc/vm_mnrv32.cpp → src/vm/tcc/vm_tgf_c.cpp
View File

File diff suppressed because it is too large Load Diff