/* $NetBSD: cpu.c,v 1.9 1996/11/23 03:53:48 mark Exp $ */ /* * Copyright (c) 1995 Mark Brinicombe. * Copyright (c) 1995 Brini. * 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. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Brini. * 4. The name of the company nor the name of the author may be used to * endorse or promote products derived from this software without specific * prior written permission. * * THIS SOFTWARE IS PROVIDED BY BRINI ``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 BRINI 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. * * RiscBSD kernel project * * cpu.c * * Probing and configuration for the master cpu * * Created : 10/10/95 */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "cpu.h" #if NCPU != 1 #error Need 1 CPU configured #endif /* Array of cpu structures, one per possible cpu */ cpu_t cpus[MAX_CPUS]; char cpu_model[48]; extern int cpu_ctrl; /* Control bits for boot CPU */ volatile int undefined_test; /* Used for FPA test */ /* Declare prototypes */ /* Prototypes */ void identify_master_cpu __P((int cpu_number, char *dev_name)); void identify_arm_cpu __P((int cpu_number)); void identify_arm_fpu __P((int cpu_number)); extern int initialise_arm_fpe __P((cpu_t *cpu)); extern int initialise_fpe __P((cpu_t *cpu)); /* * int cpumatch(struct device *parent, void *match, void *aux) * * Probe for the main cpu. Currently all this does is return 1 to * indicate that the cpu was found. */ int cpumatch(parent, match, aux) struct device *parent; void *match; void *aux; { struct device *dev = match; if (dev->dv_unit == 0) return(1); return(0); } /* * void cpusattach(struct device *parent, struct device *dev, void *aux) * * Attach the main cpu */ void cpuattach(parent, self, aux) struct device *parent; struct device *self; void *aux; { int loop; for (loop = 0; loop < MAX_CPUS; ++loop) bzero(&cpus[loop], sizeof(cpu_t)); identify_master_cpu(CPU_MASTER, self->dv_xname); } struct cfattach cpu_ca = { sizeof(struct cpu_softc), cpumatch, cpuattach }; struct cfdriver cpu_cd = { NULL, "cpu", DV_DULL, 1 }; /* * Used to test for an FPA. The following function is installed as a coproc1 * handler on the undefined instruction vector and then we issue a FPA * instruction. If undefined_test is non zero then the FPA did not handle * the instruction so must be absent. */ int fpa_test(address, instruction, frame) u_int address; u_int instruction; trapframe_t *frame; { ++undefined_test; return(0); } /* * If an FPA was found then this function is installed as the coproc1 handler * on the undefined instruction vector. Currently we don't support FPA's * so this just triggers an exception. */ int fpa_handler(address, instruction, frame, fault_code) u_int address; u_int instruction; trapframe_t *frame; int fault_code; { u_int fpsr; __asm __volatile("stmfd sp!, {r0}; .word 0xee300110; mov %0, r0; ldmfd sp!, {r0}" : "=r" (fpsr)); printf("FPA exception: fpsr = %08x\n", fpsr); return(1); } /* * Identify the master (boot) CPU * This also probes for an FPU and will install an FPE if necessary */ void identify_master_cpu(cpu_number, dev_name) int cpu_number; char *dev_name; { u_int fpsr; cpus[cpu_number].cpu_class = CPU_CLASS_ARM; cpus[cpu_number].cpu_host = CPU_HOST_MAINBUS; cpus[cpu_number].cpu_flags = CPU_FLAG_PRESENT; cpus[cpu_number].cpu_ctrl = cpu_ctrl; /* Get the cpu ID from coprocessor 15 */ cpus[cpu_number].cpu_id = cpu_id(); identify_arm_cpu(cpu_number); strcpy(cpu_model, cpus[cpu_number].cpu_model); if (cpus[CPU_MASTER].cpu_class == CPU_CLASS_SARM && (cpus[CPU_MASTER].cpu_id & CPU_ID_REVISION_MASK) < 3) { printf("%s: SA-110 with bugged STM^ instruction\n", dev_name); } /* * Ok now we test for an FPA * At this point no floating point emulator has been installed. * This means any FP instruction will cause undefined exception. * We install a temporay coproc 1 handler which will modify undefined_test * if it is called. * We then try to read the FP status register. If undefined_test has been * decremented then the instruction was not handled by an FPA so we know * the FPA is missing. If undefined_test is still 1 then we know the * instruction was handled by an FPA. * We then remove our test handler and look at the * FP status register for identification. */ install_coproc_handler(FP_COPROC, fpa_test); undefined_test = 0; __asm __volatile("stmfd sp!, {r0}; .word 0xee300110; mov %0, r0; ldmfd sp!, {r0}" : "=r" (fpsr)); if (undefined_test == 0) { cpus[cpu_number].fpu_type = (fpsr >> 24); switch (fpsr >> 24) { case 0x81 : cpus[cpu_number].fpu_class = FPU_CLASS_FPA; break; default : cpus[cpu_number].fpu_class = FPU_CLASS_FPU; break; } cpus[cpu_number].fpu_flags = 0; install_coproc_handler(FP_COPROC, fpa_handler); } else { cpus[cpu_number].fpu_class = FPU_CLASS_NONE; cpus[cpu_number].fpu_flags = 0; /* * Ok if ARMFPE is defined and the boot options request the ARM FPE then * it will be installed as the FPE. If the installation fails the existing * FPE is used as a fall back. * If either ARMFPE is not defined or the boot args did not request it the * old FPE is installed. * This is just while I work on integrating the new FPE. * It means the new FPE gets installed if compiled int (ARMFPE defined) * and also gives me a on/off option when I boot in case the new FPE is * causing panics. * In all cases it falls back on the existing FPE is the ARMFPE was not * successfully installed. */ #ifdef ARMFPE if (boot_args) { char *ptr; ptr = strstr(boot_args, "noarmfpe"); if (!ptr) { if (initialise_arm_fpe(&cpus[cpu_number]) != 0) { identify_arm_fpu(cpu_number); #ifdef FPE initialise_fpe(&cpus[cpu_number]); #endif } #ifdef FPE } else initialise_fpe(&cpus[cpu_number]); } else initialise_fpe(&cpus[cpu_number]); #else } } #endif #else #ifdef FPE initialise_fpe(&cpus[cpu_number]); #else #error No FPE built in #endif #endif } identify_arm_fpu(cpu_number); } /* * Report the type of the specifed arm processor. This uses the generic and * arm specific information in the cpu structure to identify the processor. * The remaining fields in the cpu structure are filled in appropriately. */ void identify_arm_cpu(cpu_number) int cpu_number; { cpu_t *cpu; u_int cpuid; cpu = &cpus[cpu_number]; if (cpu->cpu_host == CPU_HOST_NONE || cpu->cpu_class == CPU_CLASS_NONE) { printf("No installed processor\n"); return; } if (cpu->cpu_class != CPU_CLASS_ARM && cpu->cpu_class != CPU_CLASS_SARM) { printf("identify_arm_cpu: Can only identify ARM CPU's\n"); return; } cpuid = cpu->cpu_id; if (cpuid == 0) { printf("Processor failed probe - no CPU ID\n"); return; } /* if ((cpuid & CPU_ID_DESIGNER_MASK) != CPU_ID_ARM_LTD) printf("Unrecognised designer ID = %08x\n", cpuid);*/ switch (cpuid & CPU_ID_CPU_MASK) { case ID_ARM610: cpu->cpu_type = cpuid & CPU_ID_CPU_MASK; break; case ID_ARM710 : case ID_ARM700 : cpu->cpu_type = (cpuid & CPU_ID_CPU_MASK) >> 4; break; case ID_ARM810 : cpu->cpu_type = (cpuid & CPU_ID_CPU_MASK) >> 4; break; case ID_SARM110 : cpu->cpu_type = (cpuid & CPU_ID_CPU_MASK) >> 4; cpu->cpu_class = CPU_CLASS_SARM; sprintf(cpu->cpu_model, "SA-110 rev %d", cpuid & CPU_ID_REVISION_MASK); break; default : printf("Unrecognised processor ID = %08x\n", cpuid); cpu->cpu_type = cpuid & CPU_ID_CPU_MASK; break; } if (cpu->cpu_class == CPU_CLASS_ARM) { sprintf(cpu->cpu_model, "ARM%x rev %d", cpu->cpu_type, cpuid & CPU_ID_REVISION_MASK); if ((cpu->cpu_ctrl & CPU_CONTROL_IDC_ENABLE) == 0) strcat(cpu->cpu_model, " IDC disabled"); else strcat(cpu->cpu_model, " IDC enabled"); } else if (cpu->cpu_class == CPU_CLASS_SARM) { if ((cpu->cpu_ctrl & CPU_CONTROL_DC_ENABLE) == 0) strcat(cpu->cpu_model, " DC disabled"); else strcat(cpu->cpu_model, " DC enabled"); if ((cpu->cpu_ctrl & CPU_CONTROL_IC_ENABLE) == 0) strcat(cpu->cpu_model, " IC disabled"); else strcat(cpu->cpu_model, " IC enabled"); } if ((cpu->cpu_ctrl & CPU_CONTROL_WBUF_ENABLE) == 0) strcat(cpu->cpu_model, " WB disabled"); else strcat(cpu->cpu_model, " WB enabled"); if (cpu->cpu_ctrl & CPU_CONTROL_LABT_ENABLE) strcat(cpu->cpu_model, " LABT"); else strcat(cpu->cpu_model, " EABT"); /* Print the info */ printf(": %s\n", cpu->cpu_model); } /* * Report the type of the specifed arm fpu. This uses the generic and arm * specific information in the cpu structure to identify the fpu. The * remaining fields in the cpu structure are filled in appropriately. */ void identify_arm_fpu(cpu_number) int cpu_number; { cpu_t *cpu; cpu = &cpus[cpu_number]; if (cpu->cpu_host == CPU_HOST_NONE || cpu->cpu_class == CPU_CLASS_NONE) { printf("No installed processor\n"); return; } if (cpu->cpu_class != CPU_CLASS_ARM && cpu->cpu_class != CPU_CLASS_SARM) { printf("identify_arm_cpu: Can only identify ARM hosted FPUs\n"); return; } /* Now for the FP info */ switch (cpu->fpu_class) { case FPU_CLASS_NONE : strcpy(cpu->fpu_model, "None"); break; case FPU_CLASS_FPE : printf("fpe%d at cpu%d: %s\n", cpu_number, cpu_number, cpu->fpu_model); printf("fpe%d: no hardware found\n", cpu_number); break; case FPU_CLASS_FPA : printf("fpe%d at cpu%d: %s\n", cpu_number, cpu_number, cpu->fpu_model); if (cpu->fpu_type == FPU_TYPE_FPA11) { strcpy(cpu->fpu_model, "FPA11"); printf("fpe%d: FPA11 found\n", cpu_number); } else { strcpy(cpu->fpu_model, "FPA"); printf("fpe%d: FPA10 found\n", cpu_number); } if ((cpu->fpu_flags & 4) == 0) strcat(cpu->fpu_model, ""); else strcat(cpu->fpu_model, " clk/2"); break; case FPU_CLASS_FPU : sprintf(cpu->fpu_model, "Unknown FPU (ID=%02x)\n", cpu->fpu_type); printf("fpu%d at cpu%d: %s\n", cpu_number, cpu_number, cpu->fpu_model); break; } } int cpuopen(dev, flag, mode, p) dev_t dev; int flag; int mode; struct proc *p; { struct cpu_softc *sc; int unit; int s; unit = minor(dev); if (unit >= cpu_cd.cd_ndevs) return(ENXIO); sc = cpu_cd.cd_devs[unit]; if (!sc) return(ENXIO); s = splhigh(); if (sc->sc_open) { (void)splx(s); return(EBUSY); } ++sc->sc_open; (void)splx(s); return(0); } int cpuclose(dev, flag, mode, p) dev_t dev; int flag; int mode; struct proc *p; { struct cpu_softc *sc; int unit; int s; unit = minor(dev); sc = cpu_cd.cd_devs[unit]; if (sc->sc_open == 0) return(ENXIO); s = splhigh(); --sc->sc_open; (void)splx(s); return(0); } int cpuioctl(dev, cmd, data, flag, p) dev_t dev; int cmd; caddr_t data; int flag; struct proc *p; { struct cpu_softc *sc; int unit; unit = minor(dev); sc = cpu_cd.cd_devs[unit]; switch (cmd) { default: return(ENXIO); break; } return(0); } /* End of cpu.c */