/* Copyright 2016-2023 Free Software Foundation, Inc. Contributed by Dimitar Dimitrov This file is part of the PRU simulator. This library is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, see . */ #ifndef PRU_H #define PRU_H #include #include "opcode/pru.h" /* Needed for handling the dual PRU address space. */ #define IMEM_ADDR_MASK ((1u << 23) - 1) #define IMEM_ADDR_DEFAULT 0x20000000 /* Define memory sizes to allocate for simulated target. Sizes are artificially large to accommodate execution of compiler test suite. Please synchronize with the linker script for prusim target. */ #define DMEM_DEFAULT_SIZE (64 * 1024 * 1024) /* 16-bit word addressable space. */ #define IMEM_DEFAULT_SIZE (64 * 4 * 1024) /* For AM335x SoCs. */ #define XFRID_SCRATCH_BANK_0 10 #define XFRID_SCRATCH_BANK_1 11 #define XFRID_SCRATCH_BANK_2 12 #define XFRID_SCRATCH_BANK_PEER 14 #define XFRID_MAX 255 #define CPU (*pru_cpu) #define PC (CPU.pc) #define PC_byteaddr ((PC << 2) | PC_ADDR_SPACE_MARKER) /* Various opcode fields. */ #define RS1 extract_regval (CPU.regs[GET_INSN_FIELD (RS1, inst)], \ GET_INSN_FIELD (RS1SEL, inst)) #define RS2 extract_regval (CPU.regs[GET_INSN_FIELD (RS2, inst)], \ GET_INSN_FIELD (RS2SEL, inst)) #define RS2_w0 extract_regval (CPU.regs[GET_INSN_FIELD (RS2, inst)], \ RSEL_15_0) #define XBBO_BASEREG (CPU.regs[GET_INSN_FIELD (RS1, inst)]) #define RS1SEL GET_INSN_FIELD (RS1SEL, inst) #define RS1_WIDTH regsel_width (RS1SEL) #define RDSEL GET_INSN_FIELD (RDSEL, inst) #define RD_WIDTH regsel_width (RDSEL) #define RD_REGN GET_INSN_FIELD (RD, inst) #define IO GET_INSN_FIELD (IO, inst) #define IMM8 GET_INSN_FIELD (IMM8, inst) #define IMM16 GET_INSN_FIELD (IMM16, inst) #define WAKEONSTATUS GET_INSN_FIELD (WAKEONSTATUS, inst) #define CB GET_INSN_FIELD (CB, inst) #define RDB GET_INSN_FIELD (RDB, inst) #define XFR_WBA GET_INSN_FIELD (XFR_WBA, inst) #define LOOP_JMPOFFS GET_INSN_FIELD (LOOP_JMPOFFS, inst) #define BROFF ((uint32_t) GET_BROFF_SIGNED (inst)) #define _BURSTLEN_CALCULATE(BITFIELD) \ ((BITFIELD) >= LSSBBO_BYTECOUNT_R0_BITS7_0 ? \ (CPU.regs[0] >> ((BITFIELD) - LSSBBO_BYTECOUNT_R0_BITS7_0) * 8) & 0xff \ : (BITFIELD) + 1) #define BURSTLEN _BURSTLEN_CALCULATE (GET_BURSTLEN (inst)) #define XFR_LENGTH _BURSTLEN_CALCULATE (GET_INSN_FIELD (XFR_LENGTH, inst)) #define DO_XIN(wba,regn,rdb,l) \ pru_sim_xin (sd, cpu, (wba), (regn), (rdb), (l)) #define DO_XOUT(wba,regn,rdb,l) \ pru_sim_xout (sd, cpu, (wba), (regn), (rdb), (l)) #define DO_XCHG(wba,regn,rdb,l) \ pru_sim_xchg (sd, cpu, (wba), (regn), (rdb), (l)) #define RAISE_SIGILL(sd) sim_engine_halt ((sd), NULL, NULL, PC_byteaddr, \ sim_stopped, SIM_SIGILL) #define RAISE_SIGINT(sd) sim_engine_halt ((sd), NULL, NULL, PC_byteaddr, \ sim_stopped, SIM_SIGINT) #define MAC_R25_MAC_MODE_MASK (1u << 0) #define MAC_R25_ACC_CARRY_MASK (1u << 1) #define CARRY CPU.carry #define CTABLE CPU.ctable #define PC_ADDR_SPACE_MARKER CPU.pc_addr_space_marker #define LOOPTOP CPU.loop.looptop #define LOOPEND CPU.loop.loopend #define LOOP_IN_PROGRESS CPU.loop.loop_in_progress #define LOOPCNT CPU.loop.loop_counter /* 32 GP registers plus PC. */ #define NUM_REGS 33 /* The machine state. This state is maintained in host byte order. The fetch/store register functions must translate between host byte order and the target processor byte order. Keeping this data in target byte order simplifies the register read/write functions. Keeping this data in host order improves the performance of the simulator. Simulation speed is deemed more important. */ /* For clarity, please keep the same relative order in this enum as in the corresponding group of GP registers. In PRU ISA, Multiplier-Accumulator-Unit's registers are like "shadows" of the GP registers. MAC registers are implicitly addressed when executing the XIN/XOUT instructions to access them. Transfer to/from a MAC register can happen only from/to its corresponding GP peer register. */ enum pru_macreg_id { /* MAC register CPU GP register Description. */ PRU_MACREG_MODE, /* r25 */ /* Mode (MUL/MAC). */ PRU_MACREG_PROD_L, /* r26 */ /* Lower 32 bits of product. */ PRU_MACREG_PROD_H, /* r27 */ /* Higher 32 bits of product. */ PRU_MACREG_OP_0, /* r28 */ /* First operand. */ PRU_MACREG_OP_1, /* r29 */ /* Second operand. */ PRU_MACREG_ACC_L, /* N/A */ /* Accumulator (not exposed) */ PRU_MACREG_ACC_H, /* N/A */ /* Higher 32 bits of MAC accumulator. */ PRU_MAC_NREGS }; struct pru_regset { uint32_t regs[32]; /* Primary registers. */ uint16_t pc; /* IMEM _word_ address. */ uint32_t pc_addr_space_marker; /* IMEM virtual linker offset. This is the artificial offset that we invent in order to "separate" the DMEM and IMEM memory spaces. */ unsigned int carry : 1; uint32_t ctable[32]; /* Constant offsets table for xBCO. */ uint32_t macregs[PRU_MAC_NREGS]; uint32_t scratchpads[XFRID_MAX + 1][32]; struct { uint16_t looptop; /* LOOP top (PC of loop instr). */ uint16_t loopend; /* LOOP end (PC of loop end label). */ int loop_in_progress; /* Whether to check for PC==loopend. */ uint32_t loop_counter; /* LOOP counter. */ } loop; int cycles; int insts; }; #define PRU_SIM_CPU(cpu) ((struct pru_regset *) CPU_ARCH_DATA (cpu)) #endif /* PRU_H */