/* * QEMU model of the Milkymist programmable FPU. * * Copyright (c) 2010 Michael Walle * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, see . * * * Specification available at: * http://www.milkymist.org/socdoc/pfpu.pdf * */ #include "hw.h" #include "sysbus.h" #include "trace.h" #include "qemu-log.h" #include "qemu-error.h" #include /* #define TRACE_EXEC */ #ifdef TRACE_EXEC # define D_EXEC(x) x #else # define D_EXEC(x) #endif enum { R_CTL = 0, R_MESHBASE, R_HMESHLAST, R_VMESHLAST, R_CODEPAGE, R_VERTICES, R_COLLISIONS, R_STRAYWRITES, R_LASTDMA, R_PC, R_DREGBASE, R_CODEBASE, R_MAX }; enum { CTL_START_BUSY = (1<<0), }; enum { OP_NOP = 0, OP_FADD, OP_FSUB, OP_FMUL, OP_FABS, OP_F2I, OP_I2F, OP_VECTOUT, OP_SIN, OP_COS, OP_ABOVE, OP_EQUAL, OP_COPY, OP_IF, OP_TSIGN, OP_QUAKE, }; enum { GPR_X = 0, GPR_Y = 1, GPR_FLAGS = 2, }; enum { LATENCY_FADD = 5, LATENCY_FSUB = 5, LATENCY_FMUL = 7, LATENCY_FABS = 2, LATENCY_F2I = 2, LATENCY_I2F = 3, LATENCY_VECTOUT = 0, LATENCY_SIN = 4, LATENCY_COS = 4, LATENCY_ABOVE = 2, LATENCY_EQUAL = 2, LATENCY_COPY = 2, LATENCY_IF = 2, LATENCY_TSIGN = 2, LATENCY_QUAKE = 2, MAX_LATENCY = 7 }; #define GPR_BEGIN 0x100 #define GPR_END 0x17f #define MICROCODE_BEGIN 0x200 #define MICROCODE_END 0x3ff #define MICROCODE_WORDS 2048 #define REINTERPRET_CAST(type, val) (*((type *)&(val))) #ifdef TRACE_EXEC static const char *opcode_to_str[] = { "NOP", "FADD", "FSUB", "FMUL", "FABS", "F2I", "I2F", "VECTOUT", "SIN", "COS", "ABOVE", "EQUAL", "COPY", "IF", "TSIGN", "QUAKE", }; #endif struct MilkymistPFPUState { SysBusDevice busdev; MemoryRegion regs_region; CharDriverState *chr; qemu_irq irq; uint32_t regs[R_MAX]; uint32_t gp_regs[128]; uint32_t microcode[MICROCODE_WORDS]; int output_queue_pos; uint32_t output_queue[MAX_LATENCY]; }; typedef struct MilkymistPFPUState MilkymistPFPUState; static inline target_phys_addr_t get_dma_address(uint32_t base, uint32_t x, uint32_t y) { return base + 8 * (128 * y + x); } static inline void output_queue_insert(MilkymistPFPUState *s, uint32_t val, int pos) { s->output_queue[(s->output_queue_pos + pos) % MAX_LATENCY] = val; } static inline uint32_t output_queue_remove(MilkymistPFPUState *s) { return s->output_queue[s->output_queue_pos]; } static inline void output_queue_advance(MilkymistPFPUState *s) { s->output_queue[s->output_queue_pos] = 0; s->output_queue_pos = (s->output_queue_pos + 1) % MAX_LATENCY; } static int pfpu_decode_insn(MilkymistPFPUState *s) { uint32_t pc = s->regs[R_PC]; uint32_t insn = s->microcode[pc]; uint32_t reg_a = (insn >> 18) & 0x7f; uint32_t reg_b = (insn >> 11) & 0x7f; uint32_t op = (insn >> 7) & 0xf; uint32_t reg_d = insn & 0x7f; uint32_t r = 0; int latency = 0; switch (op) { case OP_NOP: break; case OP_FADD: { float a = REINTERPRET_CAST(float, s->gp_regs[reg_a]); float b = REINTERPRET_CAST(float, s->gp_regs[reg_b]); float t = a + b; r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_FADD; D_EXEC(qemu_log("ADD a=%f b=%f t=%f, r=%08x\n", a, b, t, r)); } break; case OP_FSUB: { float a = REINTERPRET_CAST(float, s->gp_regs[reg_a]); float b = REINTERPRET_CAST(float, s->gp_regs[reg_b]); float t = a - b; r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_FSUB; D_EXEC(qemu_log("SUB a=%f b=%f t=%f, r=%08x\n", a, b, t, r)); } break; case OP_FMUL: { float a = REINTERPRET_CAST(float, s->gp_regs[reg_a]); float b = REINTERPRET_CAST(float, s->gp_regs[reg_b]); float t = a * b; r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_FMUL; D_EXEC(qemu_log("MUL a=%f b=%f t=%f, r=%08x\n", a, b, t, r)); } break; case OP_FABS: { float a = REINTERPRET_CAST(float, s->gp_regs[reg_a]); float t = fabsf(a); r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_FABS; D_EXEC(qemu_log("ABS a=%f t=%f, r=%08x\n", a, t, r)); } break; case OP_F2I: { float a = REINTERPRET_CAST(float, s->gp_regs[reg_a]); int32_t t = a; r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_F2I; D_EXEC(qemu_log("F2I a=%f t=%d, r=%08x\n", a, t, r)); } break; case OP_I2F: { int32_t a = REINTERPRET_CAST(int32_t, s->gp_regs[reg_a]); float t = a; r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_I2F; D_EXEC(qemu_log("I2F a=%08x t=%f, r=%08x\n", a, t, r)); } break; case OP_VECTOUT: { uint32_t a = cpu_to_be32(s->gp_regs[reg_a]); uint32_t b = cpu_to_be32(s->gp_regs[reg_b]); target_phys_addr_t dma_ptr = get_dma_address(s->regs[R_MESHBASE], s->gp_regs[GPR_X], s->gp_regs[GPR_Y]); cpu_physical_memory_write(dma_ptr, (uint8_t *)&a, 4); cpu_physical_memory_write(dma_ptr + 4, (uint8_t *)&b, 4); s->regs[R_LASTDMA] = dma_ptr + 4; D_EXEC(qemu_log("VECTOUT a=%08x b=%08x dma=%08x\n", a, b, dma_ptr)); trace_milkymist_pfpu_vectout(a, b, dma_ptr); } break; case OP_SIN: { int32_t a = REINTERPRET_CAST(int32_t, s->gp_regs[reg_a]); float t = sinf(a * (1.0f / (M_PI * 4096.0f))); r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_SIN; D_EXEC(qemu_log("SIN a=%d t=%f, r=%08x\n", a, t, r)); } break; case OP_COS: { int32_t a = REINTERPRET_CAST(int32_t, s->gp_regs[reg_a]); float t = cosf(a * (1.0f / (M_PI * 4096.0f))); r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_COS; D_EXEC(qemu_log("COS a=%d t=%f, r=%08x\n", a, t, r)); } break; case OP_ABOVE: { float a = REINTERPRET_CAST(float, s->gp_regs[reg_a]); float b = REINTERPRET_CAST(float, s->gp_regs[reg_b]); float t = (a > b) ? 1.0f : 0.0f; r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_ABOVE; D_EXEC(qemu_log("ABOVE a=%f b=%f t=%f, r=%08x\n", a, b, t, r)); } break; case OP_EQUAL: { float a = REINTERPRET_CAST(float, s->gp_regs[reg_a]); float b = REINTERPRET_CAST(float, s->gp_regs[reg_b]); float t = (a == b) ? 1.0f : 0.0f; r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_EQUAL; D_EXEC(qemu_log("EQUAL a=%f b=%f t=%f, r=%08x\n", a, b, t, r)); } break; case OP_COPY: { r = s->gp_regs[reg_a]; latency = LATENCY_COPY; D_EXEC(qemu_log("COPY")); } break; case OP_IF: { float a = REINTERPRET_CAST(float, s->gp_regs[reg_a]); float b = REINTERPRET_CAST(float, s->gp_regs[reg_b]); uint32_t f = s->gp_regs[GPR_FLAGS]; float t = (f != 0) ? a : b; r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_IF; D_EXEC(qemu_log("IF f=%u a=%f b=%f t=%f, r=%08x\n", f, a, b, t, r)); } break; case OP_TSIGN: { float a = REINTERPRET_CAST(float, s->gp_regs[reg_a]); float b = REINTERPRET_CAST(float, s->gp_regs[reg_b]); float t = (b < 0) ? -a : a; r = REINTERPRET_CAST(uint32_t, t); latency = LATENCY_TSIGN; D_EXEC(qemu_log("TSIGN a=%f b=%f t=%f, r=%08x\n", a, b, t, r)); } break; case OP_QUAKE: { uint32_t a = s->gp_regs[reg_a]; r = 0x5f3759df - (a >> 1); latency = LATENCY_QUAKE; D_EXEC(qemu_log("QUAKE a=%d r=%08x\n", a, r)); } break; default: error_report("milkymist_pfpu: unknown opcode %d", op); break; } if (!reg_d) { D_EXEC(qemu_log("%04d %8s R%03d, R%03d \n", s->regs[R_PC], opcode_to_str[op], reg_a, reg_b, latency, s->regs[R_PC] + latency)); } else { D_EXEC(qemu_log("%04d %8s R%03d, R%03d -> R%03d\n", s->regs[R_PC], opcode_to_str[op], reg_a, reg_b, latency, s->regs[R_PC] + latency, reg_d)); } if (op == OP_VECTOUT) { return 0; } /* store output for this cycle */ if (reg_d) { uint32_t val = output_queue_remove(s); D_EXEC(qemu_log("R%03d <- 0x%08x\n", reg_d, val)); s->gp_regs[reg_d] = val; } output_queue_advance(s); /* store op output */ if (op != OP_NOP) { output_queue_insert(s, r, latency-1); } /* advance PC */ s->regs[R_PC]++; return 1; }; static void pfpu_start(MilkymistPFPUState *s) { int x, y; int i; for (y = 0; y <= s->regs[R_VMESHLAST]; y++) { for (x = 0; x <= s->regs[R_HMESHLAST]; x++) { D_EXEC(qemu_log("\nprocessing x=%d y=%d\n", x, y)); /* set current position */ s->gp_regs[GPR_X] = x; s->gp_regs[GPR_Y] = y; /* run microcode on this position */ i = 0; while (pfpu_decode_insn(s)) { /* decode at most MICROCODE_WORDS instructions */ if (i++ >= MICROCODE_WORDS) { error_report("milkymist_pfpu: too many instructions " "executed in microcode. No VECTOUT?"); break; } } /* reset pc for next run */ s->regs[R_PC] = 0; } } s->regs[R_VERTICES] = x * y; trace_milkymist_pfpu_pulse_irq(); qemu_irq_pulse(s->irq); } static inline int get_microcode_address(MilkymistPFPUState *s, uint32_t addr) { return (512 * s->regs[R_CODEPAGE]) + addr - MICROCODE_BEGIN; } static uint64_t pfpu_read(void *opaque, target_phys_addr_t addr, unsigned size) { MilkymistPFPUState *s = opaque; uint32_t r = 0; addr >>= 2; switch (addr) { case R_CTL: case R_MESHBASE: case R_HMESHLAST: case R_VMESHLAST: case R_CODEPAGE: case R_VERTICES: case R_COLLISIONS: case R_STRAYWRITES: case R_LASTDMA: case R_PC: case R_DREGBASE: case R_CODEBASE: r = s->regs[addr]; break; case GPR_BEGIN ... GPR_END: r = s->gp_regs[addr - GPR_BEGIN]; break; case MICROCODE_BEGIN ... MICROCODE_END: r = s->microcode[get_microcode_address(s, addr)]; break; default: error_report("milkymist_pfpu: read access to unknown register 0x" TARGET_FMT_plx, addr << 2); break; } trace_milkymist_pfpu_memory_read(addr << 2, r); return r; } static void pfpu_write(void *opaque, target_phys_addr_t addr, uint64_t value, unsigned size) { MilkymistPFPUState *s = opaque; trace_milkymist_pfpu_memory_write(addr, value); addr >>= 2; switch (addr) { case R_CTL: if (value & CTL_START_BUSY) { pfpu_start(s); } break; case R_MESHBASE: case R_HMESHLAST: case R_VMESHLAST: case R_CODEPAGE: case R_VERTICES: case R_COLLISIONS: case R_STRAYWRITES: case R_LASTDMA: case R_PC: case R_DREGBASE: case R_CODEBASE: s->regs[addr] = value; break; case GPR_BEGIN ... GPR_END: s->gp_regs[addr - GPR_BEGIN] = value; break; case MICROCODE_BEGIN ... MICROCODE_END: s->microcode[get_microcode_address(s, addr)] = value; break; default: error_report("milkymist_pfpu: write access to unknown register 0x" TARGET_FMT_plx, addr << 2); break; } } static const MemoryRegionOps pfpu_mmio_ops = { .read = pfpu_read, .write = pfpu_write, .valid = { .min_access_size = 4, .max_access_size = 4, }, .endianness = DEVICE_NATIVE_ENDIAN, }; static void milkymist_pfpu_reset(DeviceState *d) { MilkymistPFPUState *s = container_of(d, MilkymistPFPUState, busdev.qdev); int i; for (i = 0; i < R_MAX; i++) { s->regs[i] = 0; } for (i = 0; i < 128; i++) { s->gp_regs[i] = 0; } for (i = 0; i < MICROCODE_WORDS; i++) { s->microcode[i] = 0; } s->output_queue_pos = 0; for (i = 0; i < MAX_LATENCY; i++) { s->output_queue[i] = 0; } } static int milkymist_pfpu_init(SysBusDevice *dev) { MilkymistPFPUState *s = FROM_SYSBUS(typeof(*s), dev); sysbus_init_irq(dev, &s->irq); memory_region_init_io(&s->regs_region, &pfpu_mmio_ops, s, "milkymist-pfpu", MICROCODE_END * 4); sysbus_init_mmio(dev, &s->regs_region); return 0; } static const VMStateDescription vmstate_milkymist_pfpu = { .name = "milkymist-pfpu", .version_id = 1, .minimum_version_id = 1, .minimum_version_id_old = 1, .fields = (VMStateField[]) { VMSTATE_UINT32_ARRAY(regs, MilkymistPFPUState, R_MAX), VMSTATE_UINT32_ARRAY(gp_regs, MilkymistPFPUState, 128), VMSTATE_UINT32_ARRAY(microcode, MilkymistPFPUState, MICROCODE_WORDS), VMSTATE_INT32(output_queue_pos, MilkymistPFPUState), VMSTATE_UINT32_ARRAY(output_queue, MilkymistPFPUState, MAX_LATENCY), VMSTATE_END_OF_LIST() } }; static void milkymist_pfpu_class_init(ObjectClass *klass, void *data) { DeviceClass *dc = DEVICE_CLASS(klass); SysBusDeviceClass *k = SYS_BUS_DEVICE_CLASS(klass); k->init = milkymist_pfpu_init; dc->reset = milkymist_pfpu_reset; dc->vmsd = &vmstate_milkymist_pfpu; } static TypeInfo milkymist_pfpu_info = { .name = "milkymist-pfpu", .parent = TYPE_SYS_BUS_DEVICE, .instance_size = sizeof(MilkymistPFPUState), .class_init = milkymist_pfpu_class_init, }; static void milkymist_pfpu_register_types(void) { type_register_static(&milkymist_pfpu_info); } type_init(milkymist_pfpu_register_types)