adds faster decoding to tcc and cleans up others
This commit is contained in:
parent
bd0d15f3a2
commit
6e52af168b
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@ -218,7 +218,7 @@ private:
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});
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}
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}
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typename arch::traits<ARCH>::opcode_e decodeInstr(decoding_tree_node* node, code_word_t word){
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typename arch::traits<ARCH>::opcode_e decode_instr(decoding_tree_node* node, code_word_t word){
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if(!node->children.size()){
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if(node->instrs.size() == 1) return node->instrs[0].op;
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for(auto instr : node->instrs){
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@ -228,7 +228,7 @@ private:
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else{
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for(auto child : node->children){
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if (child->value == (node->submask&word)){
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return decodeInstr(child, word);
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return decode_instr(child, word);
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}
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}
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}
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@ -260,7 +260,6 @@ constexpr size_t bit_count(uint32_t u) {
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template <typename ARCH>
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vm_impl<ARCH>::vm_impl(ARCH &core, unsigned core_id, unsigned cluster_id)
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: vm_base<ARCH>(core, core_id, cluster_id) {
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unsigned id=0;
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root = new decoding_tree_node(std::numeric_limits<uint32_t>::max());
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for(auto instr:instr_descr){
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root->instrs.push_back(instr);
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@ -297,7 +296,7 @@ typename vm_base<ARCH>::virt_addr_t vm_impl<ARCH>::execute_inst(finish_cond_e co
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} else {
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if (is_jump_to_self_enabled(cond) &&
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(instr == 0x0000006f || (instr&0xffff)==0xa001)) throw simulation_stopped(0); // 'J 0' or 'C.J 0'
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auto inst_id = decodeInstr(root, instr);
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auto inst_id = decode_instr(root, instr);
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// pre execution stuff
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this->core.reg.last_branch = 0;
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if(this->sync_exec && PRE_SYNC) this->do_sync(PRE_SYNC, static_cast<unsigned>(inst_id));
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@ -121,57 +121,7 @@ protected:
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}
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}
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// some compile time constants
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// enum { MASK16 = 0b1111110001100011, MASK32 = 0b11111111111100000111000001111111 };
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enum { MASK16 = 0b1111111111111111, MASK32 = 0b11111111111100000111000001111111 };
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enum { EXTR_MASK16 = MASK16 >> 2, EXTR_MASK32 = MASK32 >> 2 };
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enum { LUT_SIZE = 1 << util::bit_count(static_cast<uint32_t>(EXTR_MASK32)), LUT_SIZE_C = 1 << util::bit_count(static_cast<uint32_t>(EXTR_MASK16)) };
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std::array<compile_func, LUT_SIZE> lut;
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std::array<compile_func, LUT_SIZE_C> lut_00, lut_01, lut_10;
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std::array<compile_func, LUT_SIZE> lut_11;
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std::array<compile_func *, 4> qlut;
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std::array<const uint32_t, 4> lutmasks = {{EXTR_MASK16, EXTR_MASK16, EXTR_MASK16, EXTR_MASK32}};
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void expand_bit_mask(int pos, uint32_t mask, uint32_t value, uint32_t valid, uint32_t idx, compile_func lut[],
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compile_func f) {
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if (pos < 0) {
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lut[idx] = f;
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} else {
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auto bitmask = 1UL << pos;
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if ((mask & bitmask) == 0) {
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expand_bit_mask(pos - 1, mask, value, valid, idx, lut, f);
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} else {
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if ((valid & bitmask) == 0) {
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expand_bit_mask(pos - 1, mask, value, valid, (idx << 1), lut, f);
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expand_bit_mask(pos - 1, mask, value, valid, (idx << 1) + 1, lut, f);
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} else {
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auto new_val = idx << 1;
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if ((value & bitmask) != 0) new_val++;
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expand_bit_mask(pos - 1, mask, value, valid, new_val, lut, f);
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}
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}
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}
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}
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inline uint32_t extract_fields(uint32_t val) { return extract_fields(29, val >> 2, lutmasks[val & 0x3], 0); }
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uint32_t extract_fields(int pos, uint32_t val, uint32_t mask, uint32_t lut_val) {
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if (pos >= 0) {
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auto bitmask = 1UL << pos;
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if ((mask & bitmask) == 0) {
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lut_val = extract_fields(pos - 1, val, mask, lut_val);
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} else {
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auto new_val = lut_val << 1;
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if ((val & bitmask) != 0) new_val++;
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lut_val = extract_fields(pos - 1, val, mask, new_val);
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}
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}
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return lut_val;
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}
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template<unsigned W, typename U, typename S = typename std::make_signed<U>::type>
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inline S sext(U from) {
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auto mask = (1ULL<<W) - 1;
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@ -183,14 +133,23 @@ private:
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/****************************************************************************
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* start opcode definitions
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****************************************************************************/
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struct InstructionDesriptor {
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struct instruction_descriptor {
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size_t length;
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uint32_t value;
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uint32_t mask;
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compile_func op;
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};
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struct decoding_tree_node{
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std::vector<instruction_descriptor> instrs;
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std::vector<decoding_tree_node*> children;
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uint32_t submask = std::numeric_limits<uint32_t>::max();
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uint32_t value;
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decoding_tree_node(uint32_t value) : value(value){}
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};
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const std::array<InstructionDesriptor, ${instructions.size}> instr_descr = {{
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decoding_tree_node* root {nullptr};
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const std::array<instruction_descriptor, ${instructions.size}> instr_descr = {{
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/* entries are: size, valid value, valid mask, function ptr */<%instructions.each{instr -> %>
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/* instruction ${instr.instruction.name}, encoding '${instr.encoding}' */
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{${instr.length}, ${instr.encoding}, ${instr.mask}, &this_class::__${generator.functionName(instr.name)}},<%}%>
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@ -228,11 +187,64 @@ private:
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vm_impl::gen_trap_check(tu);
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return BRANCH;
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}
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//decoding functionality
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void populate_decoding_tree(decoding_tree_node* root){
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//create submask
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for(auto instr: root->instrs){
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root->submask &= instr.mask;
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}
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//put each instr according to submask&encoding into children
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for(auto instr: root->instrs){
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bool foundMatch = false;
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for(auto child: root->children){
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//use value as identifying trait
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if(child->value == (instr.value&root->submask)){
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child->instrs.push_back(instr);
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foundMatch = true;
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}
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}
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if(!foundMatch){
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decoding_tree_node* child = new decoding_tree_node(instr.value&root->submask);
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child->instrs.push_back(instr);
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root->children.push_back(child);
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}
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}
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root->instrs.clear();
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//call populate_decoding_tree for all children
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if(root->children.size() >1)
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for(auto child: root->children){
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populate_decoding_tree(child);
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}
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else{
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//sort instrs by value of the mask, this works bc we want to have the least restrictive one last
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std::sort(root->children[0]->instrs.begin(), root->children[0]->instrs.end(), [](const instruction_descriptor& instr1, const instruction_descriptor& instr2) {
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return instr1.mask > instr2.mask;
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});
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}
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}
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compile_func decode_instr(decoding_tree_node* node, code_word_t word){
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if(!node->children.size()){
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if(node->instrs.size() == 1) return node->instrs[0].op;
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for(auto instr : node->instrs){
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if((instr.mask&word) == instr.value) return instr.op;
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}
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}
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else{
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for(auto child : node->children){
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if (child->value == (node->submask&word)){
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return decode_instr(child, word);
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}
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}
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}
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return nullptr;
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}
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};
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template <typename CODE_WORD> void debug_fn(CODE_WORD insn) {
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volatile CODE_WORD x = insn;
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insn = 2 * x;
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template <typename CODE_WORD> void debug_fn(CODE_WORD instr) {
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volatile CODE_WORD x = instr;
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instr = 2 * x;
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}
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template <typename ARCH> vm_impl<ARCH>::vm_impl() { this(new ARCH()); }
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@ -240,14 +252,11 @@ template <typename ARCH> vm_impl<ARCH>::vm_impl() { this(new ARCH()); }
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template <typename ARCH>
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vm_impl<ARCH>::vm_impl(ARCH &core, unsigned core_id, unsigned cluster_id)
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: vm_base<ARCH>(core, core_id, cluster_id) {
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qlut[0] = lut_00.data();
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qlut[1] = lut_01.data();
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qlut[2] = lut_10.data();
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qlut[3] = lut_11.data();
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for (auto instr : instr_descr) {
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auto quantrant = instr.value & 0x3;
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expand_bit_mask(29, lutmasks[quantrant], instr.value >> 2, instr.mask >> 2, 0, qlut[quantrant], instr.op);
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root = new decoding_tree_node(std::numeric_limits<uint32_t>::max());
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for(auto instr:instr_descr){
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root->instrs.push_back(instr);
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}
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populate_decoding_tree(root);
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}
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template <typename ARCH>
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@ -255,30 +264,19 @@ std::tuple<continuation_e>
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vm_impl<ARCH>::gen_single_inst_behavior(virt_addr_t &pc, unsigned int &inst_cnt, tu_builder& tu) {
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// we fetch at max 4 byte, alignment is 2
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enum {TRAP_ID=1<<16};
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code_word_t insn = 0;
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// const typename traits::addr_t upper_bits = ~traits::PGMASK;
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code_word_t instr = 0;
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phys_addr_t paddr(pc);
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auto *const data = (uint8_t *)&insn;
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paddr = this->core.v2p(pc);
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// if ((pc.val & upper_bits) != ((pc.val + 2) & upper_bits)) { // we may cross a page boundary
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// auto res = this->core.read(paddr, 2, data);
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// if (res != iss::Ok) throw trap_access(TRAP_ID, pc.val);
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// if ((insn & 0x3) == 0x3) { // this is a 32bit instruction
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// res = this->core.read(this->core.v2p(pc + 2), 2, data + 2);
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// }
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// } else {
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auto res = this->core.read(paddr, 4, data);
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auto res = this->core.read(paddr, 4, reinterpret_cast<uint8_t*>(&instr));
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if (res != iss::Ok) throw trap_access(TRAP_ID, pc.val);
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// }
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if (insn == 0x0000006f || (insn&0xffff)==0xa001) throw simulation_stopped(0); // 'J 0' or 'C.J 0'
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if (instr == 0x0000006f || (instr&0xffff)==0xa001) throw simulation_stopped(0); // 'J 0' or 'C.J 0'
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// curr pc on stack
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++inst_cnt;
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auto lut_val = extract_fields(insn);
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auto f = qlut[insn & 0x3][lut_val];
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auto f = decode_instr(root, instr);
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if (f == nullptr) {
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f = &this_class::illegal_intruction;
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}
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return (this->*f)(pc, insn, tu);
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return (this->*f)(pc, instr, tu);
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}
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template <typename ARCH> void vm_impl<ARCH>::gen_raise_trap(tu_builder& tu, uint16_t trap_id, uint16_t cause) {
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@ -298,7 +298,7 @@ private:
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});
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}
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}
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typename arch::traits<ARCH>::opcode_e decodeInstr(decoding_tree_node* node, code_word_t word){
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typename arch::traits<ARCH>::opcode_e decode_instr(decoding_tree_node* node, code_word_t word){
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if(!node->children.size()){
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if(node->instrs.size() == 1) return node->instrs[0].op;
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for(auto instr : node->instrs){
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@ -308,7 +308,7 @@ private:
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else{
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for(auto child : node->children){
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if (child->value == (node->submask&word)){
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return decodeInstr(child, word);
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return decode_instr(child, word);
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}
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}
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}
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@ -340,7 +340,6 @@ constexpr size_t bit_count(uint32_t u) {
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template <typename ARCH>
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vm_impl<ARCH>::vm_impl(ARCH &core, unsigned core_id, unsigned cluster_id)
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: vm_base<ARCH>(core, core_id, cluster_id) {
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unsigned id=0;
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root = new decoding_tree_node(std::numeric_limits<uint32_t>::max());
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for(auto instr:instr_descr){
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root->instrs.push_back(instr);
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@ -377,7 +376,7 @@ typename vm_base<ARCH>::virt_addr_t vm_impl<ARCH>::execute_inst(finish_cond_e co
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} else {
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if (is_jump_to_self_enabled(cond) &&
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(instr == 0x0000006f || (instr&0xffff)==0xa001)) throw simulation_stopped(0); // 'J 0' or 'C.J 0'
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auto inst_id = decodeInstr(root, instr);
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auto inst_id = decode_instr(root, instr);
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// pre execution stuff
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this->core.reg.last_branch = 0;
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if(this->sync_exec && PRE_SYNC) this->do_sync(PRE_SYNC, static_cast<unsigned>(inst_id));
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@ -121,57 +121,7 @@ protected:
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}
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}
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// some compile time constants
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// enum { MASK16 = 0b1111110001100011, MASK32 = 0b11111111111100000111000001111111 };
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enum { MASK16 = 0b1111111111111111, MASK32 = 0b11111111111100000111000001111111 };
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enum { EXTR_MASK16 = MASK16 >> 2, EXTR_MASK32 = MASK32 >> 2 };
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enum { LUT_SIZE = 1 << util::bit_count(static_cast<uint32_t>(EXTR_MASK32)), LUT_SIZE_C = 1 << util::bit_count(static_cast<uint32_t>(EXTR_MASK16)) };
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std::array<compile_func, LUT_SIZE> lut;
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std::array<compile_func, LUT_SIZE_C> lut_00, lut_01, lut_10;
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std::array<compile_func, LUT_SIZE> lut_11;
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std::array<compile_func *, 4> qlut;
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std::array<const uint32_t, 4> lutmasks = {{EXTR_MASK16, EXTR_MASK16, EXTR_MASK16, EXTR_MASK32}};
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void expand_bit_mask(int pos, uint32_t mask, uint32_t value, uint32_t valid, uint32_t idx, compile_func lut[],
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compile_func f) {
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if (pos < 0) {
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lut[idx] = f;
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} else {
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auto bitmask = 1UL << pos;
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if ((mask & bitmask) == 0) {
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expand_bit_mask(pos - 1, mask, value, valid, idx, lut, f);
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} else {
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if ((valid & bitmask) == 0) {
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expand_bit_mask(pos - 1, mask, value, valid, (idx << 1), lut, f);
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expand_bit_mask(pos - 1, mask, value, valid, (idx << 1) + 1, lut, f);
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} else {
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auto new_val = idx << 1;
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if ((value & bitmask) != 0) new_val++;
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expand_bit_mask(pos - 1, mask, value, valid, new_val, lut, f);
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}
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}
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}
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}
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inline uint32_t extract_fields(uint32_t val) { return extract_fields(29, val >> 2, lutmasks[val & 0x3], 0); }
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uint32_t extract_fields(int pos, uint32_t val, uint32_t mask, uint32_t lut_val) {
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if (pos >= 0) {
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auto bitmask = 1UL << pos;
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if ((mask & bitmask) == 0) {
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lut_val = extract_fields(pos - 1, val, mask, lut_val);
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} else {
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auto new_val = lut_val << 1;
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if ((val & bitmask) != 0) new_val++;
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lut_val = extract_fields(pos - 1, val, mask, new_val);
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}
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}
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return lut_val;
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}
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template<unsigned W, typename U, typename S = typename std::make_signed<U>::type>
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inline S sext(U from) {
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auto mask = (1ULL<<W) - 1;
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@ -183,14 +133,23 @@ private:
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/****************************************************************************
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* start opcode definitions
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****************************************************************************/
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struct InstructionDesriptor {
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struct instruction_descriptor {
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size_t length;
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uint32_t value;
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uint32_t mask;
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compile_func op;
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};
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struct decoding_tree_node{
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std::vector<instruction_descriptor> instrs;
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std::vector<decoding_tree_node*> children;
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uint32_t submask = std::numeric_limits<uint32_t>::max();
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uint32_t value;
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decoding_tree_node(uint32_t value) : value(value){}
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};
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const std::array<InstructionDesriptor, 87> instr_descr = {{
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decoding_tree_node* root {nullptr};
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const std::array<instruction_descriptor, 87> instr_descr = {{
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/* entries are: size, valid value, valid mask, function ptr */
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/* instruction LUI, encoding '0b00000000000000000000000000110111' */
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{32, 0b00000000000000000000000000110111, 0b00000000000000000000000001111111, &this_class::__lui},
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@ -494,14 +453,14 @@ private:
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this->gen_raise_trap(tu, 0, 2);
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}
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else{
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auto new_pc = tu.assignment(tu.ext((tu.bitwise_and((tu.add(tu.load(rs1+ traits::X0, 0),tu.constant((int16_t)sext<12>(imm),16))),tu.constant(~ 0x1,8))),32,true),32);
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auto new_pc = tu.assignment(tu.ext((tu.bitwise_and((tu.add(tu.load(rs1+ traits::X0, 0),tu.constant((int16_t)sext<12>(imm),16))),tu.constant(~0x1,8))),32,true),32);
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tu.open_if(tu.srem(new_pc,tu.constant(static_cast<uint32_t>(traits:: INSTR_ALIGNMENT),32)));
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this->gen_raise_trap(tu, 0, 0);
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tu.open_else();
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if(rd!= 0) {
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tu.store(rd + traits::X0,tu.ext((tu.add(tu.ext(cur_pc_val,32,false),tu.constant( 4,8))),32,true));
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}
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auto PC_val_v = tu.assignment("PC_val", tu.bitwise_and(new_pc,tu.constant(~ 0x1,8)),32);
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auto PC_val_v = tu.assignment("PC_val", tu.bitwise_and(new_pc,tu.constant(~0x1,8)),32);
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tu.store(traits::NEXT_PC, PC_val_v);
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tu.store(traits::LAST_BRANCH, tu.constant(2U, 2));
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tu.close_scope();
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@ -1963,7 +1922,7 @@ private:
|
|||
else{
|
||||
auto xrd = tu.assignment(tu.read_mem(traits::CSR, csr, 32),32);
|
||||
if(zimm!= 0) {
|
||||
tu.write_mem(traits::CSR, csr, tu.bitwise_and(xrd,tu.constant(~ ((uint32_t)zimm),32)));
|
||||
tu.write_mem(traits::CSR, csr, tu.bitwise_and(xrd,tu.constant(~((uint32_t)zimm),32)));
|
||||
}
|
||||
if(rd!= 0) {
|
||||
tu.store(rd + traits::X0,xrd);
|
||||
|
@ -2024,7 +1983,7 @@ private:
|
|||
this->gen_raise_trap(tu, 0, 2);
|
||||
}
|
||||
else{
|
||||
auto res = tu.assignment(tu.mul(tu.ext(tu.load(rs1+ traits::X0, 0),32,false),tu.ext(tu.load(rs2+ traits::X0, 0),32,false)),64);
|
||||
auto res = tu.assignment(tu.ext((tu.mul(tu.ext(tu.ext(tu.load(rs1+ traits::X0, 0),32,true),64,false),tu.ext(tu.ext(tu.load(rs2+ traits::X0, 0),32,true),64,false))),64,false),64);
|
||||
if(rd!=0) {
|
||||
tu.store(rd + traits::X0,tu.ext(res,32,true));
|
||||
}
|
||||
|
@ -2058,7 +2017,7 @@ private:
|
|||
this->gen_raise_trap(tu, 0, 2);
|
||||
}
|
||||
else{
|
||||
auto res = tu.assignment(tu.mul(tu.ext(tu.load(rs1+ traits::X0, 0),32,false),tu.ext(tu.load(rs2+ traits::X0, 0),32,false)),64);
|
||||
auto res = tu.assignment(tu.ext((tu.mul(tu.ext(tu.ext(tu.load(rs1+ traits::X0, 0),32,true),64,false),tu.ext(tu.ext(tu.load(rs2+ traits::X0, 0),32,true),64,false))),64,false),64);
|
||||
if(rd!=0) {
|
||||
tu.store(rd + traits::X0,tu.ext((tu.lshr(res,tu.constant(static_cast<uint32_t>(traits:: XLEN),32))),32,true));
|
||||
}
|
||||
|
@ -2092,7 +2051,7 @@ private:
|
|||
this->gen_raise_trap(tu, 0, 2);
|
||||
}
|
||||
else{
|
||||
auto res = tu.assignment(tu.mul(tu.ext(tu.load(rs1+ traits::X0, 0),32,false),tu.load(rs2+ traits::X0, 0)),64);
|
||||
auto res = tu.assignment(tu.ext((tu.mul(tu.ext(tu.ext(tu.load(rs1+ traits::X0, 0),32,true),64,false),tu.ext(tu.load(rs2+ traits::X0, 0),64,true))),64,false),64);
|
||||
if(rd!=0) {
|
||||
tu.store(rd + traits::X0,tu.ext((tu.lshr(res,tu.constant(static_cast<uint32_t>(traits:: XLEN),32))),32,true));
|
||||
}
|
||||
|
@ -2126,7 +2085,7 @@ private:
|
|||
this->gen_raise_trap(tu, 0, 2);
|
||||
}
|
||||
else{
|
||||
auto res = tu.assignment(tu.mul(tu.load(rs1+ traits::X0, 0),tu.load(rs2+ traits::X0, 0)),64);
|
||||
auto res = tu.assignment(tu.ext((tu.mul(tu.ext(tu.load(rs1+ traits::X0, 0),64,true),tu.ext(tu.load(rs2+ traits::X0, 0),64,true))),64,true),64);
|
||||
if(rd!=0) {
|
||||
tu.store(rd + traits::X0,tu.ext((tu.lshr(res,tu.constant(static_cast<uint32_t>(traits:: XLEN),32))),32,true));
|
||||
}
|
||||
|
@ -2164,13 +2123,13 @@ private:
|
|||
auto divisor = tu.assignment(tu.ext(tu.load(rs2+ traits::X0, 0),32,false),32);
|
||||
if(rd!= 0){ tu.open_if(tu.icmp(ICmpInst::ICMP_NE,divisor,tu.constant( 0,8)));
|
||||
auto MMIN = tu.assignment(tu.constant(((uint32_t)1)<<(static_cast<uint32_t>(traits:: XLEN)-1),32),32);
|
||||
tu.open_if(tu.logical_and(tu.icmp(ICmpInst::ICMP_EQ,tu.load(rs1+ traits::X0, 0),MMIN),tu.icmp(ICmpInst::ICMP_EQ,divisor,tu.constant(- 1,8))));
|
||||
tu.open_if(tu.logical_and(tu.icmp(ICmpInst::ICMP_EQ,tu.load(rs1+ traits::X0, 0),MMIN),tu.icmp(ICmpInst::ICMP_EQ,divisor,tu.constant(-1,8))));
|
||||
tu.store(rd + traits::X0,MMIN);
|
||||
tu.open_else();
|
||||
tu.store(rd + traits::X0,tu.ext((tu.sdiv(dividend,divisor)),32,true));
|
||||
tu.close_scope();
|
||||
tu.open_else();
|
||||
tu.store(rd + traits::X0,tu.constant((uint32_t)- 1,32));
|
||||
tu.store(rd + traits::X0,tu.constant((uint32_t)-1,32));
|
||||
tu.close_scope();
|
||||
}
|
||||
}
|
||||
|
@ -2209,7 +2168,7 @@ private:
|
|||
}
|
||||
tu.open_else();
|
||||
if(rd!=0) {
|
||||
tu.store(rd + traits::X0,tu.constant((uint32_t)- 1,32));
|
||||
tu.store(rd + traits::X0,tu.constant((uint32_t)-1,32));
|
||||
}
|
||||
tu.close_scope();
|
||||
}
|
||||
|
@ -2244,7 +2203,7 @@ private:
|
|||
else{
|
||||
tu.open_if(tu.icmp(ICmpInst::ICMP_NE,tu.load(rs2+ traits::X0, 0),tu.constant( 0,8)));
|
||||
auto MMIN = tu.assignment(tu.constant( 1<<(static_cast<uint32_t>(traits:: XLEN)-1),8),32);
|
||||
tu.open_if(tu.logical_and(tu.icmp(ICmpInst::ICMP_EQ,tu.load(rs1+ traits::X0, 0),MMIN),tu.icmp(ICmpInst::ICMP_EQ,tu.ext(tu.load(rs2+ traits::X0, 0),32,false),tu.constant(- 1,8))));
|
||||
tu.open_if(tu.logical_and(tu.icmp(ICmpInst::ICMP_EQ,tu.load(rs1+ traits::X0, 0),MMIN),tu.icmp(ICmpInst::ICMP_EQ,tu.ext(tu.load(rs2+ traits::X0, 0),32,false),tu.constant(-1,8))));
|
||||
if(rd!=0) {
|
||||
tu.store(rd + traits::X0,tu.constant( 0,8));
|
||||
}
|
||||
|
@ -2353,8 +2312,8 @@ private:
|
|||
pc=pc+ 2;
|
||||
gen_set_pc(tu, pc, traits::NEXT_PC);
|
||||
tu.open_scope();
|
||||
auto load_address = tu.assignment(tu.ext((tu.add(tu.load(rs1+ 8+ traits::X0, 0),tu.constant(uimm,8))),32,true),32);
|
||||
tu.store(rd+ 8 + traits::X0,tu.ext(tu.ext(tu.read_mem(traits::MEM, load_address, 32),32,false),32,true));
|
||||
auto offs = tu.assignment(tu.ext((tu.add(tu.load(rs1+ 8+ traits::X0, 0),tu.constant(uimm,8))),32,true),32);
|
||||
tu.store(rd+ 8 + traits::X0,tu.ext(tu.ext(tu.read_mem(traits::MEM, offs, 32),32,false),32,true));
|
||||
auto returnValue = std::make_tuple(CONT);
|
||||
tu.close_scope();
|
||||
vm_base<ARCH>::gen_sync(tu, POST_SYNC,58);
|
||||
|
@ -2380,8 +2339,8 @@ private:
|
|||
pc=pc+ 2;
|
||||
gen_set_pc(tu, pc, traits::NEXT_PC);
|
||||
tu.open_scope();
|
||||
auto load_address = tu.assignment(tu.ext((tu.add(tu.load(rs1+ 8+ traits::X0, 0),tu.constant(uimm,8))),32,true),32);
|
||||
tu.write_mem(traits::MEM, load_address, tu.ext(tu.load(rs2+ 8+ traits::X0, 0),32,true));
|
||||
auto offs = tu.assignment(tu.ext((tu.add(tu.load(rs1+ 8+ traits::X0, 0),tu.constant(uimm,8))),32,true),32);
|
||||
tu.write_mem(traits::MEM, offs, tu.ext(tu.load(rs2+ 8+ traits::X0, 0),32,true));
|
||||
auto returnValue = std::make_tuple(CONT);
|
||||
tu.close_scope();
|
||||
vm_base<ARCH>::gen_sync(tu, POST_SYNC,59);
|
||||
|
@ -2898,8 +2857,7 @@ private:
|
|||
}
|
||||
else{
|
||||
auto offs = tu.assignment(tu.ext((tu.add(tu.load(2+ traits::X0, 0),tu.constant(uimm,8))),32,true),32);
|
||||
auto res = tu.assignment(tu.ext(tu.read_mem(traits::MEM, offs, 32),32,false),32);
|
||||
tu.store(rd + traits::X0,tu.ext(res,32,true));
|
||||
tu.store(rd + traits::X0,tu.ext(tu.ext(tu.read_mem(traits::MEM, offs, 32),32,false),32,true));
|
||||
}
|
||||
auto returnValue = std::make_tuple(CONT);
|
||||
tu.close_scope();
|
||||
|
@ -2957,7 +2915,7 @@ private:
|
|||
gen_set_pc(tu, pc, traits::NEXT_PC);
|
||||
tu.open_scope();
|
||||
if(rs1&&rs1<static_cast<uint32_t>(traits:: RFS)) {
|
||||
auto PC_val_v = tu.assignment("PC_val", tu.bitwise_and(tu.load(rs1%static_cast<uint32_t>(traits:: RFS)+ traits::X0, 0),tu.constant(~ 0x1,8)),32);
|
||||
auto PC_val_v = tu.assignment("PC_val", tu.bitwise_and(tu.load(rs1%static_cast<uint32_t>(traits:: RFS)+ traits::X0, 0),tu.constant(~0x1,8)),32);
|
||||
tu.store(traits::NEXT_PC, PC_val_v);
|
||||
tu.store(traits::LAST_BRANCH, tu.constant(2U, 2));
|
||||
}
|
||||
|
@ -3045,7 +3003,7 @@ private:
|
|||
else{
|
||||
auto new_pc = tu.assignment(tu.load(rs1+ traits::X0, 0),32);
|
||||
tu.store(1 + traits::X0,tu.ext((tu.add(tu.ext(cur_pc_val,32,false),tu.constant( 2,8))),32,true));
|
||||
auto PC_val_v = tu.assignment("PC_val", tu.bitwise_and(new_pc,tu.constant(~ 0x1,8)),32);
|
||||
auto PC_val_v = tu.assignment("PC_val", tu.bitwise_and(new_pc,tu.constant(~0x1,8)),32);
|
||||
tu.store(traits::NEXT_PC, PC_val_v);
|
||||
tu.store(traits::LAST_BRANCH, tu.constant(2U, 2));
|
||||
}
|
||||
|
@ -3138,11 +3096,64 @@ private:
|
|||
vm_impl::gen_trap_check(tu);
|
||||
return BRANCH;
|
||||
}
|
||||
|
||||
//decoding functionality
|
||||
|
||||
void populate_decoding_tree(decoding_tree_node* root){
|
||||
//create submask
|
||||
for(auto instr: root->instrs){
|
||||
root->submask &= instr.mask;
|
||||
}
|
||||
//put each instr according to submask&encoding into children
|
||||
for(auto instr: root->instrs){
|
||||
bool foundMatch = false;
|
||||
for(auto child: root->children){
|
||||
//use value as identifying trait
|
||||
if(child->value == (instr.value&root->submask)){
|
||||
child->instrs.push_back(instr);
|
||||
foundMatch = true;
|
||||
}
|
||||
}
|
||||
if(!foundMatch){
|
||||
decoding_tree_node* child = new decoding_tree_node(instr.value&root->submask);
|
||||
child->instrs.push_back(instr);
|
||||
root->children.push_back(child);
|
||||
}
|
||||
}
|
||||
root->instrs.clear();
|
||||
//call populate_decoding_tree for all children
|
||||
if(root->children.size() >1)
|
||||
for(auto child: root->children){
|
||||
populate_decoding_tree(child);
|
||||
}
|
||||
else{
|
||||
//sort instrs by value of the mask, this works bc we want to have the least restrictive one last
|
||||
std::sort(root->children[0]->instrs.begin(), root->children[0]->instrs.end(), [](const instruction_descriptor& instr1, const instruction_descriptor& instr2) {
|
||||
return instr1.mask > instr2.mask;
|
||||
});
|
||||
}
|
||||
}
|
||||
compile_func decode_instr(decoding_tree_node* node, code_word_t word){
|
||||
if(!node->children.size()){
|
||||
if(node->instrs.size() == 1) return node->instrs[0].op;
|
||||
for(auto instr : node->instrs){
|
||||
if((instr.mask&word) == instr.value) return instr.op;
|
||||
}
|
||||
}
|
||||
else{
|
||||
for(auto child : node->children){
|
||||
if (child->value == (node->submask&word)){
|
||||
return decode_instr(child, word);
|
||||
}
|
||||
}
|
||||
}
|
||||
return nullptr;
|
||||
}
|
||||
};
|
||||
|
||||
template <typename CODE_WORD> void debug_fn(CODE_WORD insn) {
|
||||
volatile CODE_WORD x = insn;
|
||||
insn = 2 * x;
|
||||
template <typename CODE_WORD> void debug_fn(CODE_WORD instr) {
|
||||
volatile CODE_WORD x = instr;
|
||||
instr = 2 * x;
|
||||
}
|
||||
|
||||
template <typename ARCH> vm_impl<ARCH>::vm_impl() { this(new ARCH()); }
|
||||
|
@ -3150,14 +3161,11 @@ 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);
|
||||
root = new decoding_tree_node(std::numeric_limits<uint32_t>::max());
|
||||
for(auto instr:instr_descr){
|
||||
root->instrs.push_back(instr);
|
||||
}
|
||||
populate_decoding_tree(root);
|
||||
}
|
||||
|
||||
template <typename ARCH>
|
||||
|
@ -3165,30 +3173,19 @@ std::tuple<continuation_e>
|
|||
vm_impl<ARCH>::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;
|
||||
code_word_t instr = 0;
|
||||
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);
|
||||
auto res = this->core.read(paddr, 4, reinterpret_cast<uint8_t*>(&instr));
|
||||
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'
|
||||
if (instr == 0x0000006f || (instr&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];
|
||||
auto f = decode_instr(root, instr);
|
||||
if (f == nullptr) {
|
||||
f = &this_class::illegal_intruction;
|
||||
}
|
||||
return (this->*f)(pc, insn, tu);
|
||||
return (this->*f)(pc, instr, tu);
|
||||
}
|
||||
|
||||
template <typename ARCH> void vm_impl<ARCH>::gen_raise_trap(tu_builder& tu, uint16_t trap_id, uint16_t cause) {
|
||||
|
|
Loading…
Reference in New Issue