/******************************************************************************* * 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 #include #include #include #include #include #include #ifndef FMT_HEADER_ONLY #define FMT_HEADER_ONLY #endif #include #include #include namespace iss { namespace tcc { namespace ${coreDef.name.toLowerCase()} { using namespace iss::arch; using namespace iss::debugger; template class vm_impl : public iss::tcc::vm_base { public: using traits = arch::traits; using super = typename iss::tcc::vm_base; 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 mem_type_e = typename traits::mem_type_e; using addr_t = typename super::addr_t; using tu_builder = typename super::tu_builder; 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::tgt_adapter == nullptr) vm_base::tgt_adapter = new riscv_target_adapter(srv, this->get_arch()); return vm_base::tgt_adapter; } protected: using vm_base::get_reg_ptr; using this_class = vm_impl; using compile_ret_t = std::tuple; using compile_func = compile_ret_t (this_class::*)(virt_addr_t &pc, code_word_t instr, tu_builder&); inline const char *name(size_t index){return traits::reg_aliases.at(index);} void setup_module(std::string m) override { super::setup_module(m); } compile_ret_t gen_single_inst_behavior(virt_addr_t &, unsigned int &, tu_builder&) override; void gen_trap_behavior(tu_builder& tu) override; void gen_raise_trap(tu_builder& tu, uint16_t trap_id, uint16_t cause); void gen_leave_trap(tu_builder& tu, unsigned lvl); void gen_wait(tu_builder& tu, unsigned type); inline void gen_trap_check(tu_builder& tu) { tu("if(*trap_state!=0) goto trap_entry;"); } inline void gen_set_pc(tu_builder& tu, virt_addr_t pc, unsigned reg_num) { switch(reg_num){ case traits::NEXT_PC: tu("*next_pc = {:#x};", pc.val); break; case traits::PC: tu("*pc = {:#x};", pc.val); break; default: if(!tu.defined_regs[reg_num]){ tu("reg_t* reg{:02d} = (reg_t*){:#x};", reg_num, reinterpret_cast(get_reg_ptr(reg_num))); tu.defined_regs[reg_num]=true; } tu("*reg{:02d} = {:#x};", reg_num, pc.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(static_cast(EXTR_MASK32)), LUT_SIZE_C = 1 << util::bit_count(static_cast(EXTR_MASK16)) }; std::array lut; std::array lut_00, lut_01, lut_10; std::array lut_11; std::array qlut; std::array 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; } template::type> inline S sext(U from) { auto mask = (1ULL< instr_descr = {{ /* entries are: size, valid value, valid mask, function ptr */<%instructions.each{instr -> %> /* instruction ${instr.instruction.name}, encoding '${instr.encoding}' */ {${instr.length}, ${instr.encoding}, ${instr.mask}, &this_class::__${generator.functionName(instr.name)}},<%}%> }}; /* instruction definitions */<%instructions.eachWithIndex{instr, idx -> %> /* instruction ${idx}: ${instr.name} */ compile_ret_t __${generator.functionName(instr.name)}(virt_addr_t& pc, code_word_t instr, tu_builder& tu){ tu("${instr.name}_{:#010x}:", pc.val); vm_base::gen_sync(tu, PRE_SYNC,${idx}); <%instr.fields.eachLine{%>${it} <%}%>if(this->disass_enabled){ /* generate console output when executing the command */<%instr.disass.eachLine{%> ${it}<%}%> } auto cur_pc_val = tu.constant(pc.val, traits::reg_bit_widths[traits::PC]); pc=pc+ ${instr.length/8}; gen_set_pc(tu, pc, traits::NEXT_PC); tu.open_scope();<%instr.behavior.eachLine{%> ${it}<%}%> tu.close_scope(); vm_base::gen_sync(tu, POST_SYNC,${idx}); gen_trap_check(tu); return returnValue; } <%}%> /**************************************************************************** * end opcode definitions ****************************************************************************/ compile_ret_t illegal_intruction(virt_addr_t &pc, code_word_t instr, tu_builder& tu) { vm_impl::gen_sync(tu, iss::PRE_SYNC, instr_descr.size()); pc = pc + ((instr & 3) == 3 ? 4 : 2); gen_raise_trap(tu, 0, 2); // illegal instruction trap vm_impl::gen_sync(tu, iss::POST_SYNC, instr_descr.size()); vm_impl::gen_trap_check(tu); return BRANCH; } }; template void debug_fn(CODE_WORD insn) { volatile CODE_WORD x = insn; insn = 2 * x; } template vm_impl::vm_impl() { this(new ARCH()); } template vm_impl::vm_impl(ARCH &core, unsigned core_id, unsigned cluster_id) : vm_base(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 std::tuple vm_impl::gen_single_inst_behavior(virt_addr_t &pc, unsigned int &inst_cnt, tu_builder& tu) { // we fetch at max 4 byte, alignment is 2 enum {TRAP_ID=1<<16}; code_word_t insn = 0; // const typename traits::addr_t upper_bits = ~traits::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, tu); } template void vm_impl::gen_raise_trap(tu_builder& tu, uint16_t trap_id, uint16_t cause) { tu(" *trap_state = {:#x};", 0x80 << 24 | (cause << 16) | trap_id); tu.store(traits::LAST_BRANCH, tu.constant(std::numeric_limits::max(), 32)); } template void vm_impl::gen_leave_trap(tu_builder& tu, unsigned lvl) { tu("leave_trap(core_ptr, {});", lvl); tu.store(traits::NEXT_PC, tu.read_mem(traits::CSR, (lvl << 8) + 0x41, traits::XLEN)); tu.store(traits::LAST_BRANCH, tu.constant(std::numeric_limits::max(), 32)); } template void vm_impl::gen_wait(tu_builder& tu, unsigned type) { } template void vm_impl::gen_trap_behavior(tu_builder& tu) { tu("trap_entry:"); tu("enter_trap(core_ptr, *trap_state, *pc, 0);"); tu.store(traits::LAST_BRANCH, tu.constant(std::numeric_limits::max(),32)); tu("return *next_pc;"); } } // namespace mnrv32 template <> std::unique_ptr create(arch::${coreDef.name.toLowerCase()} *core, unsigned short port, bool dump) { auto ret = new ${coreDef.name.toLowerCase()}::vm_impl(*core, dump); if (port != 0) debugger::server::run_server(ret, port); return std::unique_ptr(ret); } } // namesapce tcc } // namespace iss #include #include #include namespace iss { namespace { std::array dummy = { core_factory::instance().register_creator("${coreDef.name.toLowerCase()}|m_p|tcc", [](unsigned port, void*) -> std::tuple{ auto* cpu = new iss::arch::riscv_hart_m_p(); auto vm = new tcc::${coreDef.name.toLowerCase()}::vm_impl(*cpu, false); if (port != 0) debugger::server::run_server(vm, port); return {cpu_ptr{cpu}, vm_ptr{vm}}; }), core_factory::instance().register_creator("${coreDef.name.toLowerCase()}|mu_p|tcc", [](unsigned port, void*) -> std::tuple{ auto* cpu = new iss::arch::riscv_hart_mu_p(); auto vm = new tcc::${coreDef.name.toLowerCase()}::vm_impl(*cpu, false); if (port != 0) debugger::server::run_server(vm, port); return {cpu_ptr{cpu}, vm_ptr{vm}}; }) }; } } extern "C" { bool* get_${coreDef.name.toLowerCase()}_tcc_creators() { return iss::dummy.data(); } }