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/*******************************************************************************
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* Copyright ( C ) 2021 MINRES Technologies GmbH
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* 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 implementation
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
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# ifndef _RISCV_HART_MU_P_H
# define _RISCV_HART_MU_P_H
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# include "riscv_hart_common.h"
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# include "iss/arch/traits.h"
# include "iss/instrumentation_if.h"
# include "iss/log_categories.h"
# include "iss/vm_if.h"
# ifndef FMT_HEADER_ONLY
# define FMT_HEADER_ONLY
# endif
# include <array>
# include <elfio/elfio.hpp>
# include <fmt/format.h>
# include <iomanip>
# include <sstream>
# include <type_traits>
# include <unordered_map>
# include <functional>
# include <util/bit_field.h>
# include <util/ities.h>
# include <util/sparse_array.h>
# if defined(__GNUC__)
# define likely(x) __builtin_expect(!!(x), 1)
# define unlikely(x) __builtin_expect(!!(x), 0)
# else
# define likely(x) x
# define unlikely(x) x
# endif
namespace iss {
namespace arch {
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template < typename BASE , features_e FEAT = FEAT_NONE > class riscv_hart_mu_p : public BASE {
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protected :
const std : : array < const char , 4 > lvl = { { ' U ' , ' S ' , ' H ' , ' M ' } } ;
const std : : array < const char * , 16 > trap_str = { { " "
" Instruction address misaligned " , // 0
" Instruction access fault " , // 1
" Illegal instruction " , // 2
" Breakpoint " , // 3
" Load address misaligned " , // 4
" Load access fault " , // 5
" Store/AMO address misaligned " , // 6
" Store/AMO access fault " , // 7
" Environment call from U-mode " , // 8
" Environment call from S-mode " , // 9
" Reserved " , // a
" Environment call from M-mode " , // b
" Instruction page fault " , // c
" Load page fault " , // d
" Reserved " , // e
" Store/AMO page fault " } } ;
const std : : array < const char * , 12 > irq_str = {
{ " User software interrupt " , " Supervisor software interrupt " , " Reserved " , " Machine software interrupt " ,
" User timer interrupt " , " Supervisor timer interrupt " , " Reserved " , " Machine timer interrupt " ,
" User external interrupt " , " Supervisor external interrupt " , " Reserved " , " Machine external interrupt " } } ;
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public :
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using core = BASE ;
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using this_class = riscv_hart_mu_p < BASE , FEAT > ;
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using phys_addr_t = typename core : : phys_addr_t ;
using reg_t = typename core : : reg_t ;
using addr_t = typename core : : addr_t ;
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using rd_csr_f = iss : : status ( this_class : : * ) ( unsigned addr , reg_t & ) ;
using wr_csr_f = iss : : status ( this_class : : * ) ( unsigned addr , reg_t ) ;
// primary template
template < class T , class Enable = void > struct hart_state { } ;
// specialization 32bit
template < typename T > class hart_state < T , typename std : : enable_if < std : : is_same < T , uint32_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 , 31 , 1 ) ;
// 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 ;
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static const reg_t mstatus_reset_val = 0x1800 ; // MPP set to 1
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void write_mstatus ( T val , unsigned priv_lvl ) {
auto mask = get_mask ( priv_lvl ) ;
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auto new_val = ( mstatus . backing . val & ~ mask ) | ( val & mask ) ;
mstatus = new_val ;
}
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static constexpr uint32_t get_mask ( unsigned priv_lvl ) {
# if __cplusplus < 201402L
return priv_lvl = = PRIV_U ? 0x80000011UL : priv_lvl = = PRIV_S ? 0x800de133UL : 0x807ff9ddUL ;
# else
switch ( priv_lvl ) {
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case PRIV_U : return 0x00000011UL ; // 0b1000 0000 0000 0000 0000 0000 0001 0001
default :
// +-SD
// | +-TSR
// | |+-TW
// | ||+-TVM
// | |||+-MXR
// | ||||+-SUM
// | |||||+-MPRV
// | |||||| +-XS
// | |||||| | +-FS
// | |||||| | | +-MPP
// | |||||| | | | +-SPP
// | |||||| | | | |+-MPIE
// | |||||| | | | || +-UPIE
// | ||||||/|/|/| || |+-MIE
// | ||||||/|/|/| || || +-UIE
return 0 b00000000000000000001100010011001 ;
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}
# endif
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}
} ;
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using hart_state_type = hart_state < reg_t > ;
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constexpr reg_t get_irq_mask ( size_t mode ) {
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std : : array < const reg_t , 4 > m = { {
0 b000100010001 , // U mode
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0 b001100110011 , // S mode
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0 ,
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0 b100110011001 // M mode
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} } ;
return m [ mode ] ;
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}
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constexpr reg_t get_pc_mask ( ) {
return traits < BASE > : : MISA_VAL & 0 b0100 ? ~ 1 : ~ 3 ;
}
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riscv_hart_mu_p ( ) ;
virtual ~ riscv_hart_mu_p ( ) = default ;
void reset ( uint64_t address ) override ;
std : : pair < uint64_t , bool > load_file ( std : : string name , int type = - 1 ) override ;
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 ;
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 ;
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virtual uint64_t enter_trap ( uint64_t flags ) override { return riscv_hart_mu_p : : enter_trap ( flags , fault_data , fault_data ) ; }
virtual uint64_t enter_trap ( uint64_t flags , uint64_t addr , uint64_t instr ) override ;
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virtual uint64_t leave_trap ( 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 {
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CLOG ( INFO , disass ) < < fmt : : format ( " 0x{:016x} {:40} [p:{};s:0x{:x};c:{}] " ,
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pc , instr , lvl [ this - > reg . PRIV ] , ( reg_t ) state . mstatus , this - > reg . icount ) ;
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} ;
iss : : instrumentation_if * get_instrumentation_if ( ) override { return & instr_if ; }
void setMemReadCb ( std : : function < iss : : status ( phys_addr_t , unsigned , uint8_t * const ) > const & memReadCb ) {
mem_read_cb = memReadCb ;
}
void setMemWriteCb ( std : : function < iss : : status ( phys_addr_t , unsigned , const uint8_t * const ) > const & memWriteCb ) {
mem_write_cb = memWriteCb ;
}
void set_csr ( unsigned addr , reg_t val ) {
csr [ addr & csr . page_addr_mask ] = val ;
}
protected :
struct riscv_instrumentation_if : public iss : : instrumentation_if {
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riscv_instrumentation_if ( riscv_hart_mu_p < BASE , FEAT > & arch )
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: arch ( arch ) { }
/**
* get the name of this architecture
*
* @ return the name of this architecture
*/
const std : : string core_type_name ( ) const override { return traits < BASE > : : core_type ; }
virtual uint64_t get_pc ( ) { return arch . get_pc ( ) ; } ;
virtual uint64_t get_next_pc ( ) { return arch . get_next_pc ( ) ; } ;
virtual void set_curr_instr_cycles ( unsigned cycles ) { arch . cycle_offset + = cycles - 1 ; } ;
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riscv_hart_mu_p < BASE , FEAT > & arch ;
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} ;
friend struct riscv_instrumentation_if ;
addr_t get_pc ( ) { return this - > reg . PC ; }
addr_t get_next_pc ( ) { return this - > reg . NEXT_PC ; }
virtual iss : : status read_mem ( phys_addr_t addr , unsigned length , uint8_t * const data ) ;
virtual iss : : status write_mem ( phys_addr_t addr , unsigned length , const uint8_t * const data ) ;
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iss : : status read_clic ( uint64_t addr , unsigned length , uint8_t * const data ) ;
iss : : status write_clic ( uint64_t addr , unsigned length , const uint8_t * const data ) ;
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virtual iss : : status read_csr ( unsigned addr , reg_t & val ) ;
virtual iss : : status write_csr ( unsigned addr , reg_t val ) ;
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hart_state_type state ;
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int64_t cycle_offset { 0 } ;
uint64_t mcycle_csr { 0 } ;
int64_t instret_offset { 0 } ;
uint64_t minstret_csr { 0 } ;
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reg_t fault_data ;
uint64_t tohost = tohost_dflt ;
uint64_t fromhost = fromhost_dflt ;
unsigned to_host_wr_cnt = 0 ;
riscv_instrumentation_if instr_if ;
using mem_type = util : : sparse_array < uint8_t , 1ULL < < 32 > ;
using csr_type = util : : sparse_array < typename traits < BASE > : : reg_t , 1ULL < < 12 , 12 > ;
using csr_page_type = typename csr_type : : page_type ;
mem_type mem ;
csr_type csr ;
std : : stringstream uart_buf ;
std : : unordered_map < reg_t , uint64_t > ptw ;
std : : unordered_map < uint64_t , uint8_t > atomic_reservation ;
std : : unordered_map < unsigned , rd_csr_f > csr_rd_cb ;
std : : unordered_map < unsigned , wr_csr_f > csr_wr_cb ;
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uint8_t clic_cfg_reg { 0 } ;
uint32_t clic_info_reg { 0 } ;
std : : array < uint32_t , 32 > clic_inttrig_reg ;
union clic_int_reg_t {
struct {
uint8_t ip ;
uint8_t ie ;
uint8_t attr ;
uint8_t ctl ;
} ;
uint32_t raw ;
} ;
std : : vector < clic_int_reg_t > clic_int_reg ;
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iss : : status read_csr_reg ( unsigned addr , reg_t & val ) ;
iss : : status write_csr_reg ( unsigned addr , reg_t val ) ;
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iss : : status read_null ( unsigned addr , reg_t & val ) ;
iss : : status write_null ( unsigned addr , reg_t val ) { return iss : : status : : Ok ; }
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iss : : status read_cycle ( unsigned addr , reg_t & val ) ;
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iss : : status write_cycle ( unsigned addr , reg_t val ) ;
iss : : status read_instret ( unsigned addr , reg_t & val ) ;
iss : : status write_instret ( unsigned addr , reg_t val ) ;
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iss : : status read_tvec ( unsigned addr , reg_t & val ) ;
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iss : : status read_time ( unsigned addr , reg_t & val ) ;
iss : : status read_status ( unsigned addr , reg_t & val ) ;
iss : : status write_status ( unsigned addr , reg_t val ) ;
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iss : : status write_cause ( unsigned addr , reg_t val ) ;
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iss : : status read_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 write_ip ( unsigned addr , reg_t val ) ;
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iss : : status write_ideleg ( unsigned addr , reg_t val ) ;
iss : : status write_edeleg ( unsigned addr , reg_t val ) ;
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iss : : status read_hartid ( unsigned addr , reg_t & val ) ;
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iss : : status write_epc ( unsigned addr , reg_t val ) ;
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iss : : status write_intstatus ( unsigned addr , reg_t val ) ;
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iss : : status write_intthresh ( unsigned addr , reg_t val ) ;
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iss : : status write_dcsr_dcsr ( unsigned addr , reg_t val ) ;
iss : : status read_dcsr_reg ( unsigned addr , reg_t & val ) ;
iss : : status write_dcsr_reg ( unsigned addr , reg_t val ) ;
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iss : : status read_dpc_reg ( unsigned addr , reg_t & val ) ;
iss : : status write_dpc_reg ( unsigned addr , reg_t val ) ;
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reg_t mhartid_reg { 0x0 } ;
std : : function < iss : : status ( phys_addr_t , unsigned , uint8_t * const ) > mem_read_cb ;
std : : function < iss : : status ( phys_addr_t , unsigned , const uint8_t * const ) > mem_write_cb ;
void check_interrupt ( ) ;
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bool pmp_check ( const access_type type , const uint64_t addr , const unsigned len ) ;
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uint64_t clic_base_addr { 0 } ;
unsigned clic_num_irq { 0 } ;
unsigned clic_num_trigger { 0 } ;
unsigned mcause_max_irq { 16 } ;
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inline bool debug_mode_active ( ) { return this - > reg . PRIV & 0x4 ; }
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} ;
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template < typename BASE , features_e FEAT >
riscv_hart_mu_p < BASE , FEAT > : : riscv_hart_mu_p ( )
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: state ( )
, instr_if ( * this ) {
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// reset values
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csr [ misa ] = traits < BASE > : : MISA_VAL ;
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csr [ mvendorid ] = 0x669 ;
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csr [ marchid ] = traits < BASE > : : MARCHID_VAL ;
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csr [ mimpid ] = 1 ;
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csr [ mclicbase ] = 0xc0000000 ; // TODO: should be taken from YAML file
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uart_buf . str ( " " ) ;
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for ( unsigned addr = mhpmcounter3 ; addr < = mhpmcounter31 ; + + addr ) {
csr_rd_cb [ addr ] = & this_class : : read_null ;
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csr_wr_cb [ addr ] = & this_class : : write_csr_reg ;
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}
for ( unsigned addr = mhpmcounter3h ; addr < = mhpmcounter31h ; + + addr ) {
csr_rd_cb [ addr ] = & this_class : : read_null ;
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csr_wr_cb [ addr ] = & this_class : : write_csr_reg ;
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}
for ( unsigned addr = mhpmevent3 ; addr < = mhpmevent31 ; + + addr ) {
csr_rd_cb [ addr ] = & this_class : : read_null ;
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csr_wr_cb [ addr ] = & this_class : : write_csr_reg ;
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}
for ( unsigned addr = hpmcounter3 ; addr < = hpmcounter31 ; + + addr ) {
csr_rd_cb [ addr ] = & this_class : : read_null ;
}
for ( unsigned addr = hpmcounter3h ; addr < = hpmcounter31h ; + + addr ) {
csr_rd_cb [ addr ] = & this_class : : read_null ;
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//csr_wr_cb[addr] = &this_class::write_csr_reg;
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}
// common regs
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const std : : array < unsigned , 14 > addrs { {
misa , mvendorid , marchid , mimpid ,
mepc , mtvec , mscratch , mcause , mtval ,
uepc , utvec , uscratch , ucause , utval ,
} } ;
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for ( auto addr : addrs ) {
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csr_rd_cb [ addr ] = & this_class : : read_csr_reg ;
csr_wr_cb [ addr ] = & this_class : : write_csr_reg ;
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}
// special handling & overrides
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csr_rd_cb [ time ] = & this_class : : read_time ;
csr_rd_cb [ timeh ] = & this_class : : read_time ;
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csr_rd_cb [ cycle ] = & this_class : : read_cycle ;
csr_rd_cb [ cycleh ] = & this_class : : read_cycle ;
csr_rd_cb [ instret ] = & this_class : : read_instret ;
csr_rd_cb [ instreth ] = & this_class : : read_instret ;
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csr_rd_cb [ mcycle ] = & this_class : : read_cycle ;
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csr_wr_cb [ mcycle ] = & this_class : : write_cycle ;
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csr_rd_cb [ mcycleh ] = & this_class : : read_cycle ;
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csr_wr_cb [ mcycleh ] = & this_class : : write_cycle ;
csr_rd_cb [ minstret ] = & this_class : : read_instret ;
csr_wr_cb [ minstret ] = & this_class : : write_instret ;
csr_rd_cb [ minstreth ] = & this_class : : read_instret ;
csr_wr_cb [ minstreth ] = & this_class : : write_instret ;
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csr_rd_cb [ mstatus ] = & this_class : : read_status ;
csr_wr_cb [ mstatus ] = & this_class : : write_status ;
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csr_wr_cb [ mcause ] = & this_class : : write_cause ;
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csr_rd_cb [ mtvec ] = & this_class : : read_tvec ;
csr_wr_cb [ mepc ] = & this_class : : write_epc ;
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csr_rd_cb [ mip ] = & this_class : : read_ip ;
csr_wr_cb [ mip ] = & this_class : : write_ip ;
csr_rd_cb [ mie ] = & this_class : : read_ie ;
csr_wr_cb [ mie ] = & this_class : : write_ie ;
csr_rd_cb [ mhartid ] = & this_class : : read_hartid ;
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csr_rd_cb [ mcounteren ] = & this_class : : read_null ;
csr_wr_cb [ mcounteren ] = & this_class : : write_null ;
csr_wr_cb [ misa ] = & this_class : : write_null ;
csr_wr_cb [ mvendorid ] = & this_class : : write_null ;
csr_wr_cb [ marchid ] = & this_class : : write_null ;
csr_wr_cb [ mimpid ] = & this_class : : write_null ;
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if ( FEAT & FEAT_PMP ) {
for ( size_t i = pmpaddr0 ; i < = pmpaddr15 ; + + i ) {
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csr_rd_cb [ i ] = & this_class : : read_csr_reg ;
csr_wr_cb [ i ] = & this_class : : write_csr_reg ;
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}
for ( size_t i = pmpcfg0 ; i < = pmpcfg3 ; + + i ) {
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csr_rd_cb [ i ] = & this_class : : read_csr_reg ;
csr_wr_cb [ i ] = & this_class : : write_csr_reg ;
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}
}
if ( FEAT & FEAT_EXT_N ) {
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csr_rd_cb [ mideleg ] = & this_class : : read_csr_reg ;
csr_wr_cb [ mideleg ] = & this_class : : write_ideleg ;
csr_rd_cb [ medeleg ] = & this_class : : read_csr_reg ;
csr_wr_cb [ medeleg ] = & this_class : : write_edeleg ;
csr_rd_cb [ uie ] = & this_class : : read_ie ;
csr_wr_cb [ uie ] = & this_class : : write_ie ;
csr_rd_cb [ uip ] = & this_class : : read_ip ;
csr_wr_cb [ uip ] = & this_class : : write_ip ;
csr_wr_cb [ uepc ] = & this_class : : write_epc ;
csr_rd_cb [ ustatus ] = & this_class : : read_status ;
csr_wr_cb [ ustatus ] = & this_class : : write_status ;
csr_wr_cb [ ucause ] = & this_class : : write_cause ;
csr_rd_cb [ utvec ] = & this_class : : read_tvec ;
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}
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if ( FEAT & FEAT_CLIC ) {
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csr_rd_cb [ mtvt ] = & this_class : : read_csr_reg ;
csr_wr_cb [ mtvt ] = & this_class : : write_csr_reg ;
csr_rd_cb [ mxnti ] = & this_class : : read_csr_reg ;
csr_wr_cb [ mxnti ] = & this_class : : write_csr_reg ;
csr_rd_cb [ mintstatus ] = & this_class : : read_csr_reg ;
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csr_wr_cb [ mintstatus ] = & this_class : : write_null ;
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csr_rd_cb [ mscratchcsw ] = & this_class : : read_csr_reg ;
csr_wr_cb [ mscratchcsw ] = & this_class : : write_csr_reg ;
csr_rd_cb [ mscratchcswl ] = & this_class : : read_csr_reg ;
csr_wr_cb [ mscratchcswl ] = & this_class : : write_csr_reg ;
csr_rd_cb [ mintthresh ] = & this_class : : read_csr_reg ;
csr_wr_cb [ mintthresh ] = & this_class : : write_intthresh ;
csr_rd_cb [ mclicbase ] = & this_class : : read_csr_reg ;
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csr_wr_cb [ mclicbase ] = & this_class : : write_null ;
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clic_base_addr = 0xC0000000 ;
clic_num_irq = 16 ;
clic_int_reg . resize ( clic_num_irq ) ;
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clic_cfg_reg = 0x20 ;
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clic_info_reg = ( /*CLICINTCTLBITS*/ 4U < < 21 ) + clic_num_irq ;
mcause_max_irq = clic_num_irq + 16 ;
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}
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if ( FEAT & FEAT_DEBUG ) {
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csr_wr_cb [ dscratch0 ] = & this_class : : write_dcsr_reg ;
csr_rd_cb [ dscratch0 ] = & this_class : : read_dcsr_reg ;
csr_wr_cb [ dscratch1 ] = & this_class : : write_dcsr_reg ;
csr_rd_cb [ dscratch1 ] = & this_class : : read_dcsr_reg ;
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csr_wr_cb [ dpc ] = & this_class : : write_dpc_reg ;
csr_rd_cb [ dpc ] = & this_class : : read_dpc_reg ;
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csr_wr_cb [ dcsr ] = & this_class : : write_dcsr_dcsr ;
csr_rd_cb [ dcsr ] = & this_class : : read_dcsr_reg ;
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}
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}
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template < typename BASE , features_e FEAT > std : : pair < uint64_t , bool > riscv_hart_mu_p < BASE , FEAT > : : load_file ( std : : string name , int type ) {
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FILE * fp = fopen ( name . c_str ( ) , " r " ) ;
if ( fp ) {
std : : array < char , 5 > buf ;
auto n = fread ( buf . data ( ) , 1 , 4 , fp ) ;
if ( n ! = 4 ) throw std : : runtime_error ( " input file has insufficient size " ) ;
buf [ 4 ] = 0 ;
if ( strcmp ( buf . data ( ) + 1 , " ELF " ) = = 0 ) {
fclose ( fp ) ;
// Create elfio reader
ELFIO : : elfio reader ;
// Load ELF data
if ( ! reader . load ( name ) ) throw std : : runtime_error ( " could not process elf file " ) ;
// check elf properties
if ( reader . get_class ( ) ! = ELFCLASS32 )
if ( sizeof ( reg_t ) = = 4 ) throw std : : runtime_error ( " wrong elf class in file " ) ;
if ( reader . get_type ( ) ! = ET_EXEC ) throw std : : runtime_error ( " wrong elf type in file " ) ;
if ( reader . get_machine ( ) ! = EM_RISCV ) throw std : : runtime_error ( " wrong elf machine in file " ) ;
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auto entry = reader . get_entry ( ) ;
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for ( const auto pseg : reader . segments ) {
const auto fsize = pseg - > get_file_size ( ) ; // 0x42c/0x0
const auto seg_data = pseg - > get_data ( ) ;
if ( fsize > 0 ) {
auto res = this - > write ( iss : : address_type : : PHYSICAL , iss : : access_type : : DEBUG_WRITE ,
traits < BASE > : : MEM , pseg - > get_physical_address ( ) ,
fsize , reinterpret_cast < const uint8_t * const > ( seg_data ) ) ;
if ( res ! = iss : : Ok )
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LOG ( ERR ) < < " problem writing " < < fsize < < " bytes to 0x " < < std : : hex
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< < pseg - > get_physical_address ( ) ;
}
}
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for ( const auto sec : reader . sections ) {
if ( sec - > get_name ( ) = = " .symtab " ) {
if ( SHT_SYMTAB = = sec - > get_type ( ) | |
SHT_DYNSYM = = sec - > get_type ( ) ) {
ELFIO : : symbol_section_accessor symbols ( reader , sec ) ;
auto sym_no = symbols . get_symbols_num ( ) ;
std : : string name ;
ELFIO : : Elf64_Addr value = 0 ;
ELFIO : : Elf_Xword size = 0 ;
unsigned char bind = 0 ;
unsigned char type = 0 ;
ELFIO : : Elf_Half section = 0 ;
unsigned char other = 0 ;
for ( auto i = 0U ; i < sym_no ; + + i ) {
symbols . get_symbol ( i , name , value , size , bind , type , section , other ) ;
if ( name = = " tohost " ) {
tohost = value ;
} else if ( name = = " fromhost " ) {
fromhost = value ;
}
}
}
} else if ( sec - > get_name ( ) = = " .tohost " ) {
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tohost = sec - > get_address ( ) ;
fromhost = tohost + 0x40 ;
}
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}
return std : : make_pair ( entry , true ) ;
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}
throw std : : runtime_error ( " memory load file is not a valid elf file " ) ;
}
throw std : : runtime_error ( " memory load file not found " ) ;
}
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template < typename BASE , features_e FEAT > bool riscv_hart_mu_p < BASE , FEAT > : : pmp_check ( const access_type type , const uint64_t addr , const unsigned len ) {
constexpr auto PMP_SHIFT = 2U ;
constexpr auto PMP_R = 0x1U ;
constexpr auto PMP_W = 0x2U ;
constexpr auto PMP_X = 0x4U ;
constexpr auto PMP_A = 0x18U ;
constexpr auto PMP_L = 0x80U ;
constexpr auto PMP_TOR = 0x1U ;
constexpr auto PMP_NA4 = 0x2U ;
constexpr auto PMP_NAPOT = 0x3U ;
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reg_t base = 0 ;
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auto any_active = false ;
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for ( size_t i = 0 ; i < 16 ; i + + ) {
reg_t tor = csr [ pmpaddr0 + i ] < < PMP_SHIFT ;
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uint8_t cfg = csr [ pmpcfg0 + ( i / 4 ) ] > > ( i % 4 ) ;
if ( cfg & PMP_A ) {
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any_active = true ;
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auto pmp_a = ( cfg & PMP_A ) > > 3 ;
auto is_tor = pmp_a = = PMP_TOR ;
auto is_na4 = pmp_a = = PMP_NA4 ;
reg_t mask = ( csr [ pmpaddr0 + i ] < < 1 ) | ( ! is_na4 ) ;
mask = ~ ( mask & ~ ( mask + 1 ) ) < < PMP_SHIFT ;
// Check each 4-byte sector of the access
auto any_match = false ;
auto all_match = true ;
for ( reg_t offset = 0 ; offset < len ; offset + = 1 < < PMP_SHIFT ) {
reg_t cur_addr = addr + offset ;
auto napot_match = ( ( cur_addr ^ tor ) & mask ) = = 0 ;
auto tor_match = base < = cur_addr & & cur_addr < tor ;
auto match = is_tor ? tor_match : napot_match ;
any_match | = match ;
all_match & = match ;
}
if ( any_match ) {
// If the PMP matches only a strict subset of the access, fail it
if ( ! all_match )
return false ;
return ( this - > reg . PRIV = = PRIV_M & & ! ( cfg & PMP_L ) ) | |
( type = = access_type : : READ & & ( cfg & PMP_R ) ) | |
( type = = access_type : : WRITE & & ( cfg & PMP_W ) ) | |
( type = = access_type : : FETCH & & ( cfg & PMP_X ) ) ;
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}
}
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base = tor ;
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}
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// constexpr auto pmp_num_regs = 16;
// reg_t tor_base = 0;
// auto any_active = false;
// auto lower_addr = addr >>2;
// auto upper_addr = (addr+len-1)>>2;
// for (size_t i = 0; i < pmp_num_regs; i++) {
// uint8_t cfg = csr[pmpcfg0+(i/4)]>>(i%4);
// uint8_t cfg_next = i==(pmp_num_regs-1)? 0 : csr[pmpcfg0+((i+1)/4)]>>((i+1)%4);
// auto pmpaddr = csr[pmpaddr0+i];
// if (cfg & PMP_A) {
// any_active=true;
// auto is_tor = bit_sub<3, 2>(cfg) == PMP_TOR;
// auto is_napot = bit_sub<4, 1>(cfg) && bit_sub<3, 2>(cfg_next)!= PMP_TOR;
// if(is_napot) {
// reg_t mask = bit_sub<3, 1>(cfg)?~( pmpaddr & ~(pmpaddr + 1)): 0x3fffffff;
// auto mpmpaddr = pmpaddr & mask;
// if((lower_addr&mask) == mpmpaddr && (upper_addr&mask)==mpmpaddr)
// return (this->reg.PRIV == PRIV_M && !(cfg & PMP_L)) ||
// (type == access_type::READ && (cfg & PMP_R)) ||
// (type == access_type::WRITE && (cfg & PMP_W)) ||
// (type == access_type::FETCH && (cfg & PMP_X));
// } else if(is_tor) {
// if(lower_addr>=tor_base && upper_addr<=pmpaddr)
// return (this->reg.PRIV == PRIV_M && !(cfg & PMP_L)) ||
// (type == access_type::READ && (cfg & PMP_R)) ||
// (type == access_type::WRITE && (cfg & PMP_W)) ||
// (type == access_type::FETCH && (cfg & PMP_X));
// }
// }
// tor_base = pmpaddr;
// }
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return ! any_active | | this - > reg . PRIV = = PRIV_M ;
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}
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template < typename BASE , features_e FEAT >
iss : : status riscv_hart_mu_p < BASE , FEAT > : : read ( const address_type type , const access_type access , const uint32_t space ,
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const uint64_t addr , const unsigned length , uint8_t * const data ) {
# ifndef NDEBUG
if ( access & & iss : : access_type : : DEBUG ) {
LOG ( TRACEALL ) < < " debug read of " < < length < < " bytes @addr 0x " < < std : : hex < < addr ;
} else if ( access & & iss : : access_type : : FETCH ) {
LOG ( TRACEALL ) < < " fetch of " < < length < < " bytes @addr 0x " < < std : : hex < < addr ;
} else {
LOG ( TRACE ) < < " read of " < < length < < " bytes @addr 0x " < < std : : hex < < addr ;
}
# endif
try {
switch ( space ) {
case traits < BASE > : : MEM : {
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if ( FEAT & FEAT_PMP ) {
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if ( ! pmp_check ( access , addr , length ) & & ( access & access_type : : DEBUG ) ! = access_type : : DEBUG ) {
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fault_data = addr ;
if ( access & & iss : : access_type : : DEBUG ) throw trap_access ( 0 , addr ) ;
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this - > reg . trap_state = ( 1 < < 31 ) | ( ( access = = access_type : : FETCH ? 1 : 5 ) < < 16 ) ; // issue trap 1
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return iss : : Err ;
}
}
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if ( unlikely ( ( access = = iss : : access_type : : FETCH | | access = = iss : : access_type : : DEBUG_FETCH ) & & ( addr & 0x1 ) = = 1 ) ) {
fault_data = addr ;
if ( access & & iss : : access_type : : DEBUG ) throw trap_access ( 0 , addr ) ;
this - > reg . trap_state = ( 1 < < 31 ) ; // issue trap 0
return iss : : Err ;
}
try {
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auto alignment = access = = iss : : access_type : : FETCH ? ( traits < BASE > : : MISA_VAL & 0x100 ? 2 : 4 ) : length ;
if ( alignment > 1 & & ( addr & ( alignment - 1 ) ) ) {
this - > reg . trap_state = 1 < < 31 | 4 < < 16 ;
fault_data = addr ;
return iss : : Err ;
}
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auto phys_addr = type = = iss : : address_type : : PHYSICAL ? phys_addr_t { access , space , addr } : BASE : : v2p ( iss : : addr_t { access , type , space , addr } ) ;
auto res = iss : : Err ;
if ( ( FEAT & FEAT_CLIC ) & & access ! = access_type : : FETCH & & phys_addr . val > = clic_base_addr & & ( phys_addr . val + length ) < = ( clic_base_addr + 0x5000 ) ) { //TODO: should be a constant
res = read_clic ( phys_addr . val , length , data ) ;
} else {
res = read_mem ( phys_addr , length , data ) ;
}
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if ( unlikely ( res ! = iss : : Ok ) ) {
this - > reg . trap_state = ( 1 < < 31 ) | ( 5 < < 16 ) ; // issue trap 5 (load access fault
fault_data = addr ;
}
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return res ;
} catch ( trap_access & ta ) {
this - > reg . trap_state = ( 1 < < 31 ) | ta . id ;
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fault_data = ta . addr ;
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return iss : : Err ;
}
} break ;
case traits < BASE > : : CSR : {
if ( length ! = sizeof ( reg_t ) ) return iss : : Err ;
return read_csr ( addr , * reinterpret_cast < reg_t * const > ( data ) ) ;
} break ;
case traits < BASE > : : FENCE : {
if ( ( addr + length ) > mem . size ( ) ) return iss : : Err ;
return iss : : Ok ;
} break ;
case traits < BASE > : : RES : {
auto it = atomic_reservation . find ( addr ) ;
if ( it ! = atomic_reservation . end ( ) & & it - > second ! = 0 ) {
memset ( data , 0xff , length ) ;
atomic_reservation . erase ( addr ) ;
} else
memset ( data , 0 , length ) ;
} break ;
default :
return iss : : Err ; // assert("Not supported");
}
return iss : : Ok ;
} catch ( trap_access & ta ) {
this - > reg . trap_state = ( 1 < < 31 ) | ta . id ;
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fault_data = ta . addr ;
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return iss : : Err ;
}
}
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template < typename BASE , features_e FEAT >
iss : : status riscv_hart_mu_p < BASE , FEAT > : : write ( const address_type type , const access_type access , const uint32_t space ,
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const uint64_t addr , const unsigned length , const uint8_t * const data ) {
# ifndef NDEBUG
const char * prefix = ( access & & iss : : access_type : : DEBUG ) ? " debug " : " " ;
switch ( length ) {
case 8 :
LOG ( TRACE ) < < prefix < < " write of " < < length < < " bytes (0x " < < std : : hex < < * ( uint64_t * ) & data [ 0 ] < < std : : dec
< < " ) @addr 0x " < < std : : hex < < addr ;
break ;
case 4 :
LOG ( TRACE ) < < prefix < < " write of " < < length < < " bytes (0x " < < std : : hex < < * ( uint32_t * ) & data [ 0 ] < < std : : dec
< < " ) @addr 0x " < < std : : hex < < addr ;
break ;
case 2 :
LOG ( TRACE ) < < prefix < < " write of " < < length < < " bytes (0x " < < std : : hex < < * ( uint16_t * ) & data [ 0 ] < < std : : dec
< < " ) @addr 0x " < < std : : hex < < addr ;
break ;
case 1 :
LOG ( TRACE ) < < prefix < < " write of " < < length < < " bytes (0x " < < std : : hex < < ( uint16_t ) data [ 0 ] < < std : : dec
< < " ) @addr 0x " < < std : : hex < < addr ;
break ;
default :
LOG ( TRACE ) < < prefix < < " write of " < < length < < " bytes @addr " < < addr ;
}
# endif
try {
switch ( space ) {
case traits < BASE > : : MEM : {
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if ( FEAT & FEAT_PMP ) {
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if ( ! pmp_check ( access , addr , length ) & & ( access & access_type : : DEBUG ) ! = access_type : : DEBUG ) {
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fault_data = addr ;
if ( access & & iss : : access_type : : DEBUG ) throw trap_access ( 0 , addr ) ;
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this - > reg . trap_state = ( 1 < < 31 ) | ( 7 < < 16 ) ; // issue trap 1
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return iss : : Err ;
}
}
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if ( unlikely ( ( access & & iss : : access_type : : FETCH ) & & ( addr & 0x1 ) = = 1 ) ) {
fault_data = addr ;
if ( access & & iss : : access_type : : DEBUG ) throw trap_access ( 0 , addr ) ;
this - > reg . trap_state = ( 1 < < 31 ) ; // issue trap 0
return iss : : Err ;
}
try {
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if ( length > 1 & & ( addr & ( length - 1 ) ) & & ( access & access_type : : DEBUG ) ! = access_type : : DEBUG ) {
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this - > reg . trap_state = 1 < < 31 | 6 < < 16 ;
fault_data = addr ;
return iss : : Err ;
}
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auto phys_addr = type = = iss : : address_type : : PHYSICAL ? phys_addr_t { access , space , addr } : BASE : : v2p ( iss : : addr_t { access , type , space , addr } ) ;
auto res = ( ( FEAT & FEAT_CLIC ) & & phys_addr . val > = clic_base_addr & & ( phys_addr . val + length ) < = ( clic_base_addr + 0x5000 ) ) ? //TODO: should be a constant
write_clic ( phys_addr . val , length , data ) : write_mem ( phys_addr , length , data ) ;
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if ( unlikely ( res ! = iss : : Ok ) ) {
this - > reg . trap_state = ( 1 < < 31 ) | ( 7 < < 16 ) ; // issue trap 7 (Store/AMO access fault)
fault_data = addr ;
}
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return res ;
} catch ( trap_access & ta ) {
this - > reg . trap_state = ( 1 < < 31 ) | ta . id ;
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fault_data = ta . addr ;
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return iss : : Err ;
}
phys_addr_t paddr = BASE : : v2p ( iss : : addr_t { access , type , space , addr } ) ;
if ( ( paddr . val + length ) > mem . size ( ) ) return iss : : Err ;
switch ( paddr . val ) {
case 0x10013000 : // UART0 base, TXFIFO reg
case 0x10023000 : // UART1 base, TXFIFO reg
uart_buf < < ( char ) data [ 0 ] ;
if ( ( ( char ) data [ 0 ] ) = = ' \n ' | | data [ 0 ] = = 0 ) {
// LOG(INFO)<<"UART"<<((paddr.val>>16)&0x3)<<" send
// '"<<uart_buf.str()<<"'";
std : : cout < < uart_buf . str ( ) ;
uart_buf . str ( " " ) ;
}
return iss : : Ok ;
case 0x10008000 : { // HFROSC base, hfrosccfg reg
auto & p = mem ( paddr . val / mem . page_size ) ;
auto offs = paddr . val & mem . page_addr_mask ;
std : : copy ( data , data + length , p . data ( ) + offs ) ;
auto & x = * ( p . data ( ) + offs + 3 ) ;
if ( x & 0x40 ) x | = 0x80 ; // hfroscrdy = 1 if hfroscen==1
return iss : : Ok ;
}
case 0x10008008 : { // HFROSC base, pllcfg reg
auto & p = mem ( paddr . val / mem . page_size ) ;
auto offs = paddr . val & mem . page_addr_mask ;
std : : copy ( data , data + length , p . data ( ) + offs ) ;
auto & x = * ( p . data ( ) + offs + 3 ) ;
x | = 0x80 ; // set pll lock upon writing
return iss : : Ok ;
} break ;
default : { }
}
} break ;
case traits < BASE > : : CSR : {
if ( length ! = sizeof ( reg_t ) ) return iss : : Err ;
return write_csr ( addr , * reinterpret_cast < const reg_t * > ( data ) ) ;
} break ;
case traits < BASE > : : FENCE : {
if ( ( addr + length ) > mem . size ( ) ) return iss : : Err ;
switch ( addr ) {
case 2 :
case 3 : {
ptw . clear ( ) ;
auto tvm = state . mstatus . TVM ;
return iss : : Ok ;
}
}
} break ;
case traits < BASE > : : RES : {
atomic_reservation [ addr ] = data [ 0 ] ;
} break ;
default :
return iss : : Err ;
}
return iss : : Ok ;
} catch ( trap_access & ta ) {
this - > reg . trap_state = ( 1 < < 31 ) | ta . id ;
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fault_data = ta . addr ;
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return iss : : Err ;
}
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_csr ( unsigned addr , reg_t & val ) {
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if ( addr > = csr . size ( ) ) return iss : : Err ;
auto req_priv_lvl = ( addr > > 8 ) & 0x3 ;
if ( this - > reg . PRIV < req_priv_lvl ) // not having required privileges
throw illegal_instruction_fault ( this - > fault_data ) ;
auto it = csr_rd_cb . find ( addr ) ;
if ( it = = csr_rd_cb . end ( ) | | ! it - > second ) // non existent register
throw illegal_instruction_fault ( this - > fault_data ) ;
return ( this - > * ( it - > second ) ) ( addr , val ) ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_csr ( unsigned addr , reg_t val ) {
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if ( addr > = csr . size ( ) ) return iss : : Err ;
auto req_priv_lvl = ( addr > > 8 ) & 0x3 ;
if ( this - > reg . PRIV < req_priv_lvl ) // not having required privileges
throw illegal_instruction_fault ( this - > fault_data ) ;
if ( ( addr & 0xc00 ) = = 0xc00 ) // writing to read-only region
throw illegal_instruction_fault ( this - > fault_data ) ;
auto it = csr_wr_cb . find ( addr ) ;
if ( it = = csr_wr_cb . end ( ) | | ! it - > second ) // non existent register
throw illegal_instruction_fault ( this - > fault_data ) ;
return ( this - > * ( it - > second ) ) ( addr , val ) ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_csr_reg ( unsigned addr , reg_t & val ) {
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val = csr [ addr ] ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_null ( unsigned addr , reg_t & val ) {
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val = 0 ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_csr_reg ( unsigned addr , reg_t val ) {
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csr [ addr ] = val ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_cycle ( unsigned addr , reg_t & val ) {
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auto cycle_val = this - > reg . icount + cycle_offset ;
if ( addr = = mcycle ) {
val = static_cast < reg_t > ( cycle_val ) ;
} else if ( addr = = mcycleh ) {
if ( sizeof ( typename traits < BASE > : : reg_t ) ! = 4 ) return iss : : Err ;
val = static_cast < reg_t > ( cycle_val > > 32 ) ;
}
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_cycle ( unsigned addr , reg_t val ) {
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if ( sizeof ( typename traits < BASE > : : reg_t ) ! = 4 ) {
if ( addr = = mcycleh )
return iss : : Err ;
mcycle_csr = static_cast < uint64_t > ( val ) ;
} else {
if ( addr = = mcycle ) {
mcycle_csr = ( mcycle_csr & 0xffffffff00000000 ) + val ;
} else {
mcycle_csr = ( static_cast < uint64_t > ( val ) < < 32 ) + ( mcycle_csr & 0xffffffff ) ;
}
}
cycle_offset = mcycle_csr - this - > reg . icount ; // TODO: relying on wrap-around
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_instret ( unsigned addr , reg_t & val ) {
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if ( ( addr & 0xff ) = = ( minstret & 0xff ) ) {
val = static_cast < reg_t > ( this - > reg . instret ) ;
} else if ( ( addr & 0xff ) = = ( minstreth & 0xff ) ) {
if ( sizeof ( typename traits < BASE > : : reg_t ) ! = 4 ) return iss : : Err ;
val = static_cast < reg_t > ( this - > reg . instret > > 32 ) ;
}
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_instret ( unsigned addr , reg_t val ) {
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if ( sizeof ( typename traits < BASE > : : reg_t ) ! = 4 ) {
if ( ( addr & 0xff ) = = ( minstreth & 0xff ) )
return iss : : Err ;
this - > reg . instret = static_cast < uint64_t > ( val ) ;
} else {
if ( ( addr & 0xff ) = = ( minstret & 0xff ) ) {
this - > reg . instret = ( this - > reg . instret & 0xffffffff00000000 ) + val ;
} else {
this - > reg . instret = ( static_cast < uint64_t > ( val ) < < 32 ) + ( this - > reg . instret & 0xffffffff ) ;
}
}
this - > reg . instret - - ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_time ( unsigned addr , reg_t & val ) {
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uint64_t time_val = this - > reg . icount / ( 100000000 / 32768 - 1 ) ; //-> ~3052;
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if ( addr = = time ) {
val = static_cast < reg_t > ( time_val ) ;
} else if ( addr = = timeh ) {
if ( sizeof ( typename traits < BASE > : : reg_t ) ! = 4 ) return iss : : Err ;
val = static_cast < reg_t > ( time_val > > 32 ) ;
}
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_tvec ( unsigned addr , reg_t & val ) {
val = csr [ addr ] & ~ 2 ;
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return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_status ( unsigned addr , reg_t & val ) {
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auto req_priv_lvl = ( addr > > 8 ) & 0x3 ;
val = state . mstatus & hart_state_type : : get_mask ( req_priv_lvl ) ;
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return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_status ( unsigned addr , reg_t val ) {
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auto req_priv_lvl = ( addr > > 8 ) & 0x3 ;
state . write_mstatus ( val , req_priv_lvl ) ;
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check_interrupt ( ) ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_cause ( unsigned addr , reg_t val ) {
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csr [ addr ] = val & ( ( 1UL < < ( traits < BASE > : : XLEN - 1 ) ) | ( mcause_max_irq - 1 ) ) ; //TODO: make exception code size configurable
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return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_hartid ( unsigned addr , reg_t & val ) {
val = mhartid_reg ;
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return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_ie ( unsigned addr , reg_t & val ) {
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auto mask = get_irq_mask ( ( addr > > 8 ) & 0x3 ) ;
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val = csr [ mie ] & mask ;
if ( this - > reg . PRIV ! = 3 )
val & = csr [ mideleg ] ;
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return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_ie ( unsigned addr , reg_t val ) {
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auto mask = get_irq_mask ( ( addr > > 8 ) & 0x3 ) ;
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csr [ mie ] = ( csr [ mie ] & ~ mask ) | ( val & mask ) ;
check_interrupt ( ) ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_ip ( unsigned addr , reg_t & val ) {
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auto mask = get_irq_mask ( ( addr > > 8 ) & 0x3 ) ;
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val = csr [ mip ] & mask ;
if ( this - > reg . PRIV ! = 3 )
val & = csr [ mideleg ] ;
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return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_ip ( unsigned addr , reg_t val ) {
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auto mask = get_irq_mask ( ( addr > > 8 ) & 0x3 ) ;
mask & = 0xf ; // only xSIP is writable
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csr [ mip ] = ( csr [ mip ] & ~ mask ) | ( val & mask ) ;
check_interrupt ( ) ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_ideleg ( unsigned addr , reg_t val ) {
auto mask = 0 b000100010001 ; // only U mode supported
csr [ mideleg ] = ( csr [ mideleg ] & ~ mask ) | ( val & mask ) ;
return iss : : Ok ;
}
template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_edeleg ( unsigned addr , reg_t val ) {
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auto mask = 0 b1011001111110111 ; // bit 14/10 (reserved), bit 11 (Env call), and 3 (break) are hardwired to 0
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csr [ medeleg ] = ( csr [ medeleg ] & ~ mask ) | ( val & mask ) ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_epc ( unsigned addr , reg_t val ) {
csr [ addr ] = val & get_pc_mask ( ) ;
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return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_dcsr_dcsr ( unsigned addr , reg_t val ) {
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if ( ! debug_mode_active ( ) )
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throw illegal_instruction_fault ( this - > fault_data ) ;
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// +-------------- ebreakm
// | +---------- stepi
// | | +++----- cause
// | | ||| +- step
csr [ addr ] = val & 0 b1000100111000100U ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_dcsr_reg ( unsigned addr , reg_t & val ) {
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if ( ! debug_mode_active ( ) )
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throw illegal_instruction_fault ( this - > fault_data ) ;
val = csr [ addr ] ;
return iss : : Ok ;
}
template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_dcsr_reg ( unsigned addr , reg_t val ) {
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if ( ! debug_mode_active ( ) )
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throw illegal_instruction_fault ( this - > fault_data ) ;
csr [ addr ] = val ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_dpc_reg ( unsigned addr , reg_t & val ) {
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if ( ! debug_mode_active ( ) )
throw illegal_instruction_fault ( this - > fault_data ) ;
val = this - > reg . DPC ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_dpc_reg ( unsigned addr , reg_t val ) {
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if ( ! debug_mode_active ( ) )
throw illegal_instruction_fault ( this - > fault_data ) ;
this - > reg . DPC = val ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT >
iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_intthresh ( unsigned addr , reg_t val ) {
csr [ addr ] = val & 0xff ;
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT >
iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_mem ( phys_addr_t paddr , unsigned length , uint8_t * const data ) {
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if ( mem_read_cb ) return mem_read_cb ( paddr , length , data ) ;
switch ( paddr . val ) {
case 0x0200BFF8 : { // CLINT base, mtime reg
if ( sizeof ( reg_t ) < length ) return iss : : Err ;
reg_t time_val ;
this - > read_csr ( time , time_val ) ;
std : : copy ( ( uint8_t * ) & time_val , ( ( uint8_t * ) & time_val ) + length , data ) ;
} break ;
case 0x10008000 : {
const mem_type : : page_type & p = mem ( paddr . val / mem . page_size ) ;
uint64_t offs = paddr . val & mem . page_addr_mask ;
std : : copy ( p . data ( ) + offs , p . data ( ) + offs + length , data ) ;
if ( this - > reg . icount > 30000 ) data [ 3 ] | = 0x80 ;
} break ;
default : {
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for ( auto offs = 0U ; offs < length ; + + offs ) {
* ( data + offs ) = mem [ ( paddr . val + offs ) % mem . size ( ) ] ;
}
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}
}
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT >
iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_mem ( phys_addr_t paddr , unsigned length , const uint8_t * const data ) {
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if ( mem_write_cb ) return mem_write_cb ( paddr , length , data ) ;
switch ( paddr . val ) {
case 0x10013000 : // UART0 base, TXFIFO reg
case 0x10023000 : // UART1 base, TXFIFO reg
uart_buf < < ( char ) data [ 0 ] ;
if ( ( ( char ) data [ 0 ] ) = = ' \n ' | | data [ 0 ] = = 0 ) {
// LOG(INFO)<<"UART"<<((paddr.val>>16)&0x3)<<" send
// '"<<uart_buf.str()<<"'";
std : : cout < < uart_buf . str ( ) ;
uart_buf . str ( " " ) ;
}
break ;
case 0x10008000 : { // HFROSC base, hfrosccfg reg
mem_type : : page_type & p = mem ( paddr . val / mem . page_size ) ;
size_t offs = paddr . val & mem . page_addr_mask ;
std : : copy ( data , data + length , p . data ( ) + offs ) ;
uint8_t & x = * ( p . data ( ) + offs + 3 ) ;
if ( x & 0x40 ) x | = 0x80 ; // hfroscrdy = 1 if hfroscen==1
} break ;
case 0x10008008 : { // HFROSC base, pllcfg reg
mem_type : : page_type & p = mem ( paddr . val / mem . page_size ) ;
size_t offs = paddr . val & mem . page_addr_mask ;
std : : copy ( data , data + length , p . data ( ) + offs ) ;
uint8_t & x = * ( p . data ( ) + offs + 3 ) ;
x | = 0x80 ; // set pll lock upon writing
} break ;
default : {
mem_type : : page_type & p = mem ( paddr . val / mem . page_size ) ;
std : : copy ( data , data + length , p . data ( ) + ( paddr . val & mem . page_addr_mask ) ) ;
// tohost handling in case of riscv-test
if ( paddr . access & & iss : : access_type : : FUNC ) {
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auto tohost_upper = ( traits < BASE > : : XLEN = = 32 & & paddr . val = = ( tohost + 4 ) ) | |
( traits < BASE > : : XLEN = = 64 & & paddr . val = = tohost ) ;
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auto tohost_lower =
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( traits < BASE > : : XLEN = = 32 & & paddr . val = = tohost ) | | ( traits < BASE > : : XLEN = = 64 & & paddr . val = = tohost ) ;
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if ( tohost_lower | | tohost_upper ) {
uint64_t hostvar = * reinterpret_cast < uint64_t * > ( p . data ( ) + ( tohost & mem . page_addr_mask ) ) ;
if ( tohost_upper | | ( tohost_lower & & to_host_wr_cnt > 0 ) ) {
switch ( hostvar > > 48 ) {
case 0 :
if ( hostvar ! = 0x1 ) {
LOG ( FATAL ) < < " tohost value is 0x " < < std : : hex < < hostvar < < std : : dec < < " ( " < < hostvar
< < " ), stopping simulation " ;
} else {
LOG ( INFO ) < < " tohost value is 0x " < < std : : hex < < hostvar < < std : : dec < < " ( " < < hostvar
< < " ), stopping simulation " ;
}
this - > reg . trap_state = std : : numeric_limits < uint32_t > : : max ( ) ;
this - > interrupt_sim = hostvar ;
break ;
//throw(iss::simulation_stopped(hostvar));
case 0x0101 : {
char c = static_cast < char > ( hostvar & 0xff ) ;
if ( c = = ' \n ' | | c = = 0 ) {
LOG ( INFO ) < < " tohost send ' " < < uart_buf . str ( ) < < " ' " ;
uart_buf . str ( " " ) ;
} else
uart_buf < < c ;
to_host_wr_cnt = 0 ;
} break ;
default :
break ;
}
} else if ( tohost_lower )
to_host_wr_cnt + + ;
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} else if ( ( traits < BASE > : : XLEN = = 32 & & paddr . val = = fromhost + 4 ) | |
( traits < BASE > : : XLEN = = 64 & & paddr . val = = fromhost ) ) {
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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 ;
}
}
}
}
return iss : : Ok ;
}
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void read_uint32 ( uint64_t offs , uint32_t & reg , uint8_t * const data , unsigned length ) {
auto reg_ptr = reinterpret_cast < uint8_t * > ( & reg ) ;
switch ( offs & 0x3 ) {
case 0 :
for ( auto i = 0U ; i < length ; + + i )
* ( data + i ) = * ( reg_ptr + i ) ;
break ;
case 1 :
for ( auto i = 0U ; i < length ; + + i )
* ( data + i ) = * ( reg_ptr + 1 + i ) ;
break ;
case 2 :
for ( auto i = 0U ; i < length ; + + i )
* ( data + i ) = * ( reg_ptr + 2 + i ) ;
break ;
case 3 :
* data = * ( reg_ptr + 3 ) ;
break ;
}
}
void write_uint32 ( uint64_t offs , uint32_t & reg , const uint8_t * const data , unsigned length ) {
auto reg_ptr = reinterpret_cast < uint8_t * > ( & reg ) ;
switch ( offs & 0x3 ) {
case 0 :
for ( auto i = 0U ; i < length ; + + i )
* ( reg_ptr + i ) = * ( data + i ) ;
break ;
case 1 :
for ( auto i = 0U ; i < length ; + + i )
* ( reg_ptr + 1 + i ) = * ( data + i ) ;
break ;
case 2 :
for ( auto i = 0U ; i < length ; + + i )
* ( reg_ptr + 2 + i ) = * ( data + i ) ;
break ;
case 3 :
* ( reg_ptr + 3 ) = * data ;
break ;
}
}
template < typename BASE , features_e FEAT >
iss : : status riscv_hart_mu_p < BASE , FEAT > : : read_clic ( uint64_t addr , unsigned length , uint8_t * const data ) {
if ( addr = = clic_base_addr ) { // cliccfg
* data = clic_cfg_reg ;
for ( auto i = 1 ; i < length ; + + i ) * ( data + i ) = 0 ;
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} else if ( addr > = ( clic_base_addr + 4 ) & & ( addr + length ) < = ( clic_base_addr + 8 ) ) { // clicinfo
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read_uint32 ( addr , clic_info_reg , data , length ) ;
} else if ( addr > = ( clic_base_addr + 0x40 ) & & ( addr + length ) < = ( clic_base_addr + 0x40 + clic_num_trigger * 4 ) ) { // clicinttrig
auto offset = ( ( addr & 0x7fff ) - 0x40 ) / 4 ;
read_uint32 ( addr , clic_inttrig_reg [ offset ] , data , length ) ;
} else if ( addr > = ( clic_base_addr + 0x1000 ) & & ( addr + length ) < = ( clic_base_addr + clic_num_irq * 4 ) ) { // clicintip/clicintie/clicintattr/clicintctl
auto offset = ( ( addr & 0x7fff ) - 0x1000 ) / 4 ;
read_uint32 ( addr , clic_int_reg [ offset ] . raw , data , length ) ;
} else {
for ( auto i = 0U ; i < length ; + + i ) * ( data + i ) = 0 ;
}
return iss : : Ok ;
}
template < typename BASE , features_e FEAT >
iss : : status riscv_hart_mu_p < BASE , FEAT > : : write_clic ( uint64_t addr , unsigned length , const uint8_t * const data ) {
if ( addr = = clic_base_addr ) { // cliccfg
clic_cfg_reg = * data ;
clic_cfg_reg & = 0x7f ;
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// } else if(addr>=(clic_base_addr+4) && (addr+length)<=(clic_base_addr+4)){ // clicinfo
// write_uint32(addr, clic_info_reg, data, length);
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} else if ( addr > = ( clic_base_addr + 0x40 ) & & ( addr + length ) < = ( clic_base_addr + 0xC0 ) ) { // clicinttrig
auto offset = ( ( addr & 0x7fff ) - 0x40 ) / 4 ;
write_uint32 ( addr , clic_inttrig_reg [ offset ] , data , length ) ;
} else if ( addr > = ( clic_base_addr + 0x1000 ) & & ( addr + length ) < = ( clic_base_addr + clic_num_irq * 4 ) ) { // clicintip/clicintie/clicintattr/clicintctl
auto offset = ( ( addr & 0x7fff ) - 0x1000 ) / 4 ;
write_uint32 ( addr , clic_int_reg [ offset ] . raw , data , length ) ;
}
return iss : : Ok ;
}
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template < typename BASE , features_e FEAT > inline void riscv_hart_mu_p < BASE , FEAT > : : reset ( uint64_t address ) {
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BASE : : reset ( address ) ;
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state . mstatus = hart_state_type : : mstatus_reset_val ;
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}
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template < typename BASE , features_e FEAT > void riscv_hart_mu_p < BASE , FEAT > : : check_interrupt ( ) {
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auto ideleg = csr [ mideleg ] ;
// Multiple simultaneous interrupts and traps at the same privilege level are
// handled in the following decreasing priority order:
// external interrupts, software interrupts, timer interrupts, then finally
// any synchronous traps.
auto ena_irq = csr [ mip ] & csr [ mie ] ;
bool mie = state . mstatus . MIE ;
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auto m_enabled = this - > reg . PRIV < PRIV_M | | mie ;
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auto enabled_interrupts = m_enabled ? ena_irq & ~ ideleg : 0 ;
if ( enabled_interrupts ! = 0 ) {
int res = 0 ;
while ( ( enabled_interrupts & 1 ) = = 0 ) {
enabled_interrupts > > = 1 ;
res + + ;
}
this - > reg . pending_trap = res < < 16 | 1 ; // 0x80 << 24 | (cause << 16) | trap_id
}
}
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template < typename BASE , features_e FEAT > uint64_t riscv_hart_mu_p < BASE , FEAT > : : enter_trap ( uint64_t flags , uint64_t addr , uint64_t instr ) {
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// flags are ACTIVE[31:31], CAUSE[30:16], TRAPID[15:0]
// calculate and write mcause val
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if ( flags = = std : : numeric_limits < uint64_t > : : max ( ) ) flags = this - > reg . trap_state ;
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auto trap_id = bit_sub < 0 , 16 > ( flags ) ;
auto cause = bit_sub < 16 , 15 > ( flags ) ;
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if ( trap_id = = 0 & & cause = = 11 ) cause = 0x8 + this - > reg . PRIV ; // adjust environment call cause
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// calculate effective privilege level
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auto new_priv = PRIV_M ;
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if ( trap_id = = 0 ) { // exception
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if ( this - > reg . PRIV ! = PRIV_M & & ( ( csr [ medeleg ] > > cause ) & 0x1 ) ! = 0 )
new_priv = PRIV_U ;
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// store ret addr in xepc register
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csr [ uepc | ( new_priv < < 8 ) ] = static_cast < reg_t > ( addr ) ; // store actual address instruction of exception
/*
* 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 .
*/
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switch ( cause ) {
case 0 :
csr [ utval | ( new_priv < < 8 ) ] = static_cast < reg_t > ( addr ) ;
break ;
case 2 :
csr [ utval | ( new_priv < < 8 ) ] = ( instr & 0x3 ) = = 3 ? instr : instr & 0xffff ;
break ;
case 3 :
//TODO: implement debug mode behavior
// csr[dpc] = addr;
// csr[dcsr] = (csr[dcsr] & ~0x1c3) | (1<<6) | PRIV_M; //FIXME: cause should not be 4 (stepi)
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csr [ utval | ( new_priv < < 8 ) ] = addr ;
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break ;
case 4 :
case 6 :
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case 7 :
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csr [ utval | ( new_priv < < 8 ) ] = fault_data ;
break ;
default :
csr [ utval | ( new_priv < < 8 ) ] = 0 ;
}
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fault_data = 0 ;
} else {
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if ( this - > reg . PRIV ! = PRIV_M & & ( ( csr [ mideleg ] > > cause ) & 0x1 ) ! = 0 )
new_priv = PRIV_U ;
csr [ uepc | ( new_priv < < 8 ) ] = this - > reg . NEXT_PC ; // store next address if interrupt
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this - > reg . pending_trap = 0 ;
}
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size_t adr = ucause | ( new_priv < < 8 ) ;
csr [ adr ] = ( trap_id < < 31 ) + cause ;
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// update mstatus
// xPP field of mstatus is written with the active privilege mode at the time
// of the trap; the x PIE field of mstatus
// is written with the value of the active interrupt-enable bit at the time of
// the trap; and the x IE field of mstatus
// is cleared
// store the actual privilege level in yPP and store interrupt enable flags
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switch ( new_priv ) {
case PRIV_M :
state . mstatus . MPP = this - > reg . PRIV ;
state . mstatus . MPIE = state . mstatus . MIE ;
state . mstatus . MIE = false ;
break ;
case PRIV_U :
state . mstatus . UPIE = state . mstatus . UIE ;
state . mstatus . UIE = false ;
break ;
default :
break ;
}
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// get trap vector
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auto ivec = csr [ utvec | ( new_priv < < 8 ) ] ;
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// calculate addr// set NEXT_PC to trap addressess to jump to based on MODE
// bits in mtvec
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this - > reg . NEXT_PC = ivec & ~ 0x3UL ;
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if ( ( ivec & 0x1 ) = = 1 & & trap_id ! = 0 ) this - > reg . NEXT_PC + = 4 * cause ;
std : : array < char , 32 > buffer ;
sprintf ( buffer . data ( ) , " 0x%016lx " , addr ) ;
if ( ( flags & 0xffffffff ) ! = 0xffffffff )
CLOG ( INFO , disass ) < < ( trap_id ? " Interrupt " : " Trap " ) < < " with cause ' "
< < ( trap_id ? irq_str [ cause ] : trap_str [ cause ] ) < < " ' ( " < < cause < < " ) "
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< < " at address " < < buffer . data ( ) < < " occurred, changing privilege level from "
< < lvl [ this - > reg . PRIV ] < < " to " < < lvl [ new_priv ] ;
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// reset trap state
this - > reg . PRIV = new_priv ;
this - > reg . trap_state = 0 ;
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return this - > reg . NEXT_PC ;
}
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template < typename BASE , features_e FEAT > uint64_t riscv_hart_mu_p < BASE , FEAT > : : leave_trap ( uint64_t flags ) {
auto cur_priv = this - > reg . PRIV ;
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auto inst_priv = ( flags & 0x3 ) ? 3 : 0 ;
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if ( inst_priv > cur_priv ) {
auto trap_val = 0x80ULL < < 24 | ( 2 < < 16 ) ; // illegal instruction
this - > reg . trap_state = trap_val ;
this - > reg . NEXT_PC = std : : numeric_limits < uint32_t > : : max ( ) ;
} else {
auto status = state . mstatus ;
// pop the relevant lower-privilege interrupt enable and privilege mode stack
// clear respective yIE
switch ( inst_priv ) {
case PRIV_M :
this - > reg . PRIV = state . mstatus . MPP ;
state . mstatus . MPP = 0 ; // clear mpp to U mode
state . mstatus . MIE = state . mstatus . MPIE ;
state . mstatus . MPIE = 1 ;
break ;
case PRIV_U :
this - > reg . PRIV = 0 ;
state . mstatus . UIE = state . mstatus . UPIE ;
state . mstatus . UPIE = 1 ;
break ;
}
// sets the pc to the value stored in the x epc register.
this - > reg . NEXT_PC = csr [ uepc | inst_priv < < 8 ] ;
CLOG ( INFO , disass ) < < " Executing xRET , changing privilege level from " < < lvl [ cur_priv ] < < " to "
< < lvl [ this - > reg . PRIV ] ;
check_interrupt ( ) ;
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}
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return this - > reg . NEXT_PC ;
}
} // namespace arch
} // namespace iss
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# endif /* _RISCV_HART_MU_P_H */