riscv/riscv/riscv_machdep.c

1.34    skrll /*	$NetBSD: riscv_machdep.c,v 1.34 2023/09/03 08:48:20 skrll Exp $	*/
1.12    skrll
 1.1     matt /*-
1.18    skrll  * Copyright (c) 2014, 2019, 2022 The NetBSD Foundation, Inc.
 1.1     matt  * All rights reserved.
 1.1     matt  *
 1.1     matt  * This code is derived from software contributed to The NetBSD Foundation
1.18    skrll  * by Matt Thomas of 3am Software Foundry, and by Nick Hudson.
 1.1     matt  *
 1.1     matt  * Redistribution and use in source and binary forms, with or without
 1.1     matt  * modification, are permitted provided that the following conditions
 1.1     matt  * are met:
 1.1     matt  * 1. Redistributions of source code must retain the above copyright
 1.1     matt  *    notice, this list of conditions and the following disclaimer.
 1.1     matt  * 2. Redistributions in binary form must reproduce the above copyright
 1.1     matt  *    notice, this list of conditions and the following disclaimer in the
 1.1     matt  *    documentation and/or other materials provided with the distribution.
 1.1     matt  *
 1.1     matt  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.1     matt  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.1     matt  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.1     matt  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.1     matt  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1     matt  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1     matt  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1     matt  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1     matt  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1     matt  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1     matt  * POSSIBILITY OF SUCH DAMAGE.
 1.1     matt  */
 1.1     matt
1.26    skrll #include "opt_ddb.h"
1.18    skrll #include "opt_modular.h"
1.29    skrll #include "opt_multiprocessor.h"
1.18    skrll #include "opt_riscv_debug.h"
1.18    skrll
 1.1     matt #include <sys/cdefs.h>
1.34    skrll __RCSID("$NetBSD: riscv_machdep.c,v 1.34 2023/09/03 08:48:20 skrll Exp $");
 1.1     matt
1.16    skrll #include <sys/param.h>
 1.1     matt
1.26    skrll #include <sys/asan.h>
1.18    skrll #include <sys/boot_flag.h>
 1.1     matt #include <sys/cpu.h>
 1.1     matt #include <sys/exec.h>
 1.1     matt #include <sys/kmem.h>
 1.1     matt #include <sys/ktrace.h>
1.16    skrll #include <sys/lwp.h>
 1.1     matt #include <sys/module.h>
1.26    skrll #include <sys/mount.h>
1.18    skrll #include <sys/msgbuf.h>
1.26    skrll #include <sys/optstr.h>
 1.1     matt #include <sys/proc.h>
 1.1     matt #include <sys/reboot.h>
 1.1     matt #include <sys/syscall.h>
1.26    skrll #include <sys/sysctl.h>
1.16    skrll #include <sys/systm.h>
 1.1     matt
1.18    skrll #include <dev/cons.h>
 1.1     matt #include <uvm/uvm_extern.h>
 1.1     matt
1.26    skrll #include <riscv/frame.h>
 1.1     matt #include <riscv/locore.h>
1.18    skrll #include <riscv/machdep.h>
1.18    skrll #include <riscv/pte.h>
1.26    skrll #include <riscv/sbi.h>
 1.1     matt
1.22    skrll #include <libfdt.h>
1.22    skrll #include <dev/fdt/fdtvar.h>
1.26    skrll #include <dev/fdt/fdt_boot.h>
1.22    skrll #include <dev/fdt/fdt_memory.h>
1.26    skrll #include <dev/fdt/fdt_private.h>
1.22    skrll
1.26    skrll int cpu_printfataltraps = 1;
 1.1     matt char machine[] = MACHINE;
 1.1     matt char machine_arch[] = MACHINE_ARCH;
 1.1     matt
1.18    skrll #ifdef VERBOSE_INIT_RISCV
1.20   simonb #define	VPRINTF(...)	printf(__VA_ARGS__)
1.18    skrll #else
1.20   simonb #define	VPRINTF(...)	__nothing
1.18    skrll #endif
1.18    skrll
1.26    skrll /* 64 should be enough, even for a ZFS UUID */
1.26    skrll #define	MAX_BOOT_DEV_STR	64
1.18    skrll
1.26    skrll char bootdevstr[MAX_BOOT_DEV_STR] = "";
1.18    skrll char *boot_args = NULL;
1.18    skrll
1.26    skrll paddr_t physical_start;
1.26    skrll paddr_t physical_end;
1.26    skrll
1.18    skrll static void
1.18    skrll earlyconsputc(dev_t dev, int c)
1.18    skrll {
1.18    skrll 	uartputc(c);
1.18    skrll }
1.18    skrll
1.18    skrll static int
1.18    skrll earlyconsgetc(dev_t dev)
1.18    skrll {
1.19    skrll 	return uartgetc();
1.18    skrll }
1.18    skrll
1.18    skrll static struct consdev earlycons = {
1.18    skrll 	.cn_putc = earlyconsputc,
1.18    skrll 	.cn_getc = earlyconsgetc,
1.18    skrll 	.cn_pollc = nullcnpollc,
1.18    skrll };
1.18    skrll
 1.1     matt struct vm_map *phys_map;
 1.1     matt
 1.1     matt struct trapframe cpu_ddb_regs;
 1.1     matt const pcu_ops_t * const pcu_ops_md_defs[PCU_UNIT_COUNT] = {
1.14    skrll #ifdef FPE
 1.1     matt 	[PCU_FPU] = &pcu_fpu_ops,
1.14    skrll #endif
 1.1     matt };
 1.1     matt
1.18    skrll /*
1.18    skrll  * Used by PHYSTOV and VTOPHYS -- Will be set be BSS is zeroed so
1.18    skrll  * keep it in data
1.18    skrll  */
1.18    skrll unsigned long kern_vtopdiff __attribute__((__section__(".data")));
1.18    skrll
1.26    skrll
1.26    skrll /*
1.26    skrll  * machine dependent system variables.
1.26    skrll  */
1.26    skrll SYSCTL_SETUP(sysctl_machdep_setup, "sysctl machdep subtree setup")
1.26    skrll {
1.26    skrll 	sysctl_createv(clog, 0, NULL, NULL,
1.26    skrll 	    CTLFLAG_PERMANENT,
1.26    skrll 	    CTLTYPE_NODE, "machdep", NULL,
1.26    skrll 	    NULL, 0, NULL, 0,
1.26    skrll 	    CTL_MACHDEP, CTL_EOL);
1.26    skrll }
1.26    skrll
 1.1     matt void
 1.1     matt delay(unsigned long us)
 1.1     matt {
 1.1     matt 	const uint32_t cycles_per_us = curcpu()->ci_data.cpu_cc_freq / 1000000;
 1.1     matt 	const uint64_t cycles = (uint64_t)us * cycles_per_us;
1.24   simonb 	const uint64_t finish = csr_cycle_read() + cycles;
 1.1     matt
1.24   simonb 	while (csr_cycle_read() < finish) {
 1.1     matt 		/* spin, baby spin */
 1.1     matt 	}
 1.1     matt }
 1.1     matt
 1.1     matt #ifdef MODULAR
 1.1     matt /*
1.10    skrll  * Push any modules loaded by the boot loader.
 1.1     matt  */
 1.1     matt void
 1.1     matt module_init_md(void)
 1.1     matt {
 1.1     matt }
 1.1     matt #endif /* MODULAR */
 1.1     matt
 1.1     matt /*
 1.1     matt  * Set registers on exec.
1.26    skrll  * Clear all registers except sp, pc.
1.26    skrll  * sp is set to the stack pointer passed in.  pc is set to the entry
1.26    skrll  * point given by the exec_package passed in.
 1.1     matt  */
 1.1     matt void
 1.1     matt setregs(struct lwp *l, struct exec_package *pack, vaddr_t stack)
 1.1     matt {
 1.1     matt 	struct trapframe * const tf = l->l_md.md_utf;
 1.1     matt 	struct proc * const p = l->l_proc;
 1.1     matt
1.26    skrll 	memset(tf, 0, sizeof(*tf));
 1.1     matt 	tf->tf_sp = (intptr_t)stack_align(stack);
 1.1     matt 	tf->tf_pc = (intptr_t)pack->ep_entry & ~1;
 1.1     matt #ifdef _LP64
1.25   simonb 	tf->tf_sr = (p->p_flag & PK_32) ? SR_USER32 : SR_USER64;
 1.1     matt #else
 1.1     matt 	tf->tf_sr = SR_USER;
 1.1     matt #endif
1.26    skrll
1.26    skrll 	// Set up arguments for ___start(cleanup, ps_strings)
1.26    skrll 	tf->tf_a0 = 0;			// cleanup
1.26    skrll 	tf->tf_a1 = p->p_psstrp;	// ps_strings
1.26    skrll
1.26    skrll 	/*
1.26    skrll 	 * Must have interrupts disabled for exception return.
1.26    skrll 	 * Must be switching to user mode.
1.26    skrll 	 * Must enable interrupts after sret.
1.26    skrll 	 */
1.26    skrll 	KASSERT(__SHIFTOUT(tf->tf_sr, SR_SIE) == 0);
1.26    skrll 	KASSERT(__SHIFTOUT(tf->tf_sr, SR_SPP) == 0);
1.26    skrll 	KASSERT(__SHIFTOUT(tf->tf_sr, SR_SPIE) != 0);
 1.1     matt }
 1.1     matt
 1.1     matt void
 1.4    kamil md_child_return(struct lwp *l)
 1.1     matt {
1.26    skrll 	struct trapframe * const tf = lwp_trapframe(l);
 1.1     matt
 1.1     matt 	tf->tf_a0 = 0;
 1.1     matt 	tf->tf_a1 = 1;
1.13    skrll #ifdef FPE
1.26    skrll 	/* Disable FP as we can't be using it (yet). */
1.26    skrll 	tf->tf_sr &= ~SR_FS;
1.13    skrll #endif
1.26    skrll
1.26    skrll 	/*
1.26    skrll 	 * Must have interrupts disabled for exception return.
1.26    skrll 	 * Must be switching to user mode.
1.26    skrll 	 * Must enable interrupts after sret.
1.26    skrll 	 */
1.26    skrll
1.26    skrll 	KASSERT(__SHIFTOUT(tf->tf_sr, SR_SIE) == 0);
1.26    skrll 	KASSERT(__SHIFTOUT(tf->tf_sr, SR_SPP) == 0);
1.26    skrll 	KASSERT(__SHIFTOUT(tf->tf_sr, SR_SPIE) != 0);
1.26    skrll
1.26    skrll 	userret(l);
 1.1     matt }
 1.1     matt
 1.1     matt void
 1.1     matt cpu_spawn_return(struct lwp *l)
 1.1     matt {
 1.1     matt 	userret(l);
 1.1     matt }
 1.1     matt
1.10    skrll /*
 1.1     matt  * Start a new LWP
 1.1     matt  */
 1.1     matt void
 1.1     matt startlwp(void *arg)
 1.1     matt {
 1.1     matt 	ucontext_t * const uc = arg;
 1.1     matt 	lwp_t * const l = curlwp;
 1.1     matt 	int error __diagused;
 1.1     matt
 1.1     matt 	error = cpu_setmcontext(l, &uc->uc_mcontext, uc->uc_flags);
 1.1     matt 	KASSERT(error == 0);
 1.1     matt
1.26    skrll 	kmem_free(uc, sizeof(*uc));
 1.1     matt 	userret(l);
 1.1     matt }
 1.1     matt
 1.1     matt // We've worked hard to make sure struct reg and __gregset_t are the same.
 1.1     matt // Ditto for struct fpreg and fregset_t.
 1.1     matt
1.15    skrll #ifdef _LP64
 1.1     matt CTASSERT(sizeof(struct reg) == sizeof(__gregset_t));
1.15    skrll #endif
 1.1     matt CTASSERT(sizeof(struct fpreg) == sizeof(__fregset_t));
 1.1     matt
 1.1     matt void
 1.1     matt cpu_getmcontext(struct lwp *l, mcontext_t *mcp, unsigned int *flags)
 1.1     matt {
 1.1     matt 	const struct trapframe * const tf = l->l_md.md_utf;
 1.1     matt
 1.1     matt 	/* Save register context. */
 1.1     matt 	*(struct reg *)mcp->__gregs = tf->tf_regs;
 1.1     matt
 1.1     matt 	*flags |= _UC_CPU | _UC_TLSBASE;
 1.1     matt
 1.1     matt 	/* Save floating point register context, if any. */
 1.1     matt 	KASSERT(l == curlwp);
 1.2      chs 	if (fpu_valid_p(l)) {
 1.1     matt 		/*
 1.1     matt 		 * If this process is the current FP owner, dump its
 1.1     matt 		 * context to the PCB first.
 1.1     matt 		 */
 1.2      chs 		fpu_save(l);
 1.1     matt
 1.1     matt 		struct pcb * const pcb = lwp_getpcb(l);
 1.1     matt 		*(struct fpreg *)mcp->__fregs = pcb->pcb_fpregs;
 1.1     matt 		*flags |= _UC_FPU;
 1.1     matt 	}
 1.1     matt }
 1.1     matt
 1.1     matt int
 1.1     matt cpu_mcontext_validate(struct lwp *l, const mcontext_t *mcp)
 1.1     matt {
 1.1     matt 	/*
 1.1     matt 	 * Verify that at least the PC and SP are user addresses.
 1.1     matt 	 */
 1.1     matt 	if ((intptr_t) mcp->__gregs[_REG_PC] < 0
 1.1     matt 	    || (intptr_t) mcp->__gregs[_REG_SP] < 0
 1.1     matt 	    || (mcp->__gregs[_REG_PC] & 1))
 1.1     matt 		return EINVAL;
 1.1     matt
 1.1     matt 	return 0;
 1.1     matt }
 1.1     matt
 1.1     matt int
 1.1     matt cpu_setmcontext(struct lwp *l, const mcontext_t *mcp, unsigned int flags)
 1.1     matt {
 1.1     matt 	struct trapframe * const tf = l->l_md.md_utf;
 1.1     matt 	struct proc * const p = l->l_proc;
 1.1     matt 	const __greg_t * const gr = mcp->__gregs;
 1.1     matt 	int error;
 1.1     matt
 1.1     matt 	/* Restore register context, if any. */
 1.1     matt 	if (flags & _UC_CPU) {
 1.1     matt 		error = cpu_mcontext_validate(l, mcp);
 1.1     matt 		if (error)
 1.1     matt 			return error;
 1.1     matt
1.33      rin 		/*
1.33      rin 		 * Avoid updating TLS register here.
1.33      rin 		 */
1.33      rin 		const __greg_t saved_tp = tf->tf_reg[_REG_TP];
 1.1     matt 		tf->tf_regs = *(const struct reg *)gr;
1.33      rin 		tf->tf_reg[_REG_TP] = saved_tp;
 1.1     matt 	}
 1.1     matt
 1.1     matt 	/* Restore the private thread context */
 1.1     matt 	if (flags & _UC_TLSBASE) {
1.26    skrll 		lwp_setprivate(l, (void *)(intptr_t)mcp->__gregs[_X_TP]);
 1.1     matt 	}
 1.1     matt
 1.1     matt 	/* Restore floating point register context, if any. */
 1.1     matt 	if (flags & _UC_FPU) {
 1.1     matt 		KASSERT(l == curlwp);
 1.1     matt 		/* Tell PCU we are replacing the FPU contents. */
 1.2      chs 		fpu_replace(l);
 1.1     matt
 1.1     matt 		/*
 1.1     matt 		 * The PCB FP regs struct includes the FP CSR, so use the
 1.1     matt 		 * proper size of fpreg when copying.
 1.1     matt 		 */
 1.1     matt 		struct pcb * const pcb = lwp_getpcb(l);
 1.1     matt 		pcb->pcb_fpregs = *(const struct fpreg *)mcp->__fregs;
 1.1     matt 	}
 1.1     matt
 1.1     matt 	mutex_enter(p->p_lock);
 1.1     matt 	if (flags & _UC_SETSTACK)
 1.1     matt 		l->l_sigstk.ss_flags |= SS_ONSTACK;
 1.1     matt 	if (flags & _UC_CLRSTACK)
 1.1     matt 		l->l_sigstk.ss_flags &= ~SS_ONSTACK;
 1.1     matt 	mutex_exit(p->p_lock);
 1.1     matt
1.26    skrll 	return 0;
 1.1     matt }
 1.1     matt
 1.1     matt void
 1.6       ad cpu_need_resched(struct cpu_info *ci, struct lwp *l, int flags)
 1.1     matt {
 1.1     matt 	KASSERT(kpreempt_disabled());
 1.1     matt
 1.6       ad 	if ((flags & RESCHED_KPREEMPT) != 0) {
 1.1     matt #ifdef __HAVE_PREEMPTION
 1.6       ad 		if ((flags & RESCHED_REMOTE) != 0) {
1.17    skrll 			cpu_send_ipi(ci, IPI_KPREEMPT);
 1.6       ad 		} else {
 1.1     matt 			softint_trigger(SOFTINT_KPREEMPT);
1.17    skrll 		}
 1.1     matt #endif
 1.1     matt 		return;
 1.1     matt 	}
 1.6       ad 	if ((flags & RESCHED_REMOTE) != 0) {
 1.1     matt #ifdef MULTIPROCESSOR
 1.1     matt 		cpu_send_ipi(ci, IPI_AST);
 1.1     matt #endif
 1.6       ad 	} else {
1.26    skrll 		l->l_md.md_astpending = 1;	/* force call to ast() */
 1.6       ad 	}
 1.1     matt }
 1.1     matt
 1.1     matt void
 1.1     matt cpu_signotify(struct lwp *l)
 1.1     matt {
 1.1     matt 	KASSERT(kpreempt_disabled());
 1.1     matt #ifdef __HAVE_FAST_SOFTINTS
 1.1     matt 	KASSERT(lwp_locked(l, NULL));
 1.1     matt #endif
 1.1     matt
 1.6       ad 	if (l->l_cpu != curcpu()) {
 1.6       ad #ifdef MULTIPROCESSOR
1.29    skrll 		cpu_send_ipi(l->l_cpu, IPI_AST);
 1.6       ad #endif
 1.6       ad 	} else {
 1.6       ad 		l->l_md.md_astpending = 1; 	/* force call to ast() */
 1.6       ad 	}
 1.1     matt }
 1.1     matt
 1.1     matt void
 1.1     matt cpu_need_proftick(struct lwp *l)
 1.1     matt {
 1.1     matt 	KASSERT(kpreempt_disabled());
 1.1     matt 	KASSERT(l->l_cpu == curcpu());
 1.1     matt
 1.1     matt 	l->l_pflag |= LP_OWEUPC;
 1.1     matt 	l->l_md.md_astpending = 1;		/* force call to ast() */
 1.1     matt }
 1.1     matt
1.26    skrll
1.26    skrll /* Sync the discs, unmount the filesystems, and adjust the todr */
1.26    skrll static void
1.26    skrll bootsync(void)
1.26    skrll {
1.26    skrll 	static bool bootsyncdone = false;
1.26    skrll
1.26    skrll 	if (bootsyncdone)
1.26    skrll 		return;
1.26    skrll
1.26    skrll 	bootsyncdone = true;
1.26    skrll
1.26    skrll 	/* Make sure we can still manage to do things */
1.26    skrll 	if ((csr_sstatus_read() & SR_SIE) == 0) {
1.26    skrll 		/*
1.26    skrll 		 * If we get here then boot has been called without RB_NOSYNC
1.26    skrll 		 * and interrupts were disabled. This means the boot() call
1.26    skrll 		 * did not come from a user process e.g. shutdown, but must
1.26    skrll 		 * have come from somewhere in the kernel.
1.26    skrll 		 */
1.26    skrll 		ENABLE_INTERRUPTS();
1.26    skrll 		printf("Warning interrupts disabled during boot()\n");
1.26    skrll 	}
1.26    skrll
1.26    skrll 	vfs_shutdown();
1.26    skrll
1.26    skrll 	resettodr();
1.26    skrll }
1.26    skrll
1.26    skrll
 1.1     matt void
1.26    skrll cpu_reboot(int howto, char *bootstr)
 1.1     matt {
1.26    skrll
1.26    skrll 	/*
1.26    skrll 	 * If RB_NOSYNC was not specified sync the discs.
1.26    skrll 	 * Note: Unless cold is set to 1 here, syslogd will die during the
1.26    skrll 	 * unmount.  It looks like syslogd is getting woken up only to find
1.26    skrll 	 * that it cannot page part of the binary in as the filesystem has
1.26    skrll 	 * been unmounted.
1.26    skrll 	 */
1.26    skrll 	if ((howto & RB_NOSYNC) == 0)
1.26    skrll 		bootsync();
1.26    skrll
1.26    skrll #if 0
1.26    skrll 	/* Disable interrupts. */
1.26    skrll 	const int s = splhigh();
1.26    skrll
1.26    skrll 	/* Do a dump if requested. */
1.26    skrll 	if ((howto & (RB_DUMP | RB_HALT)) == RB_DUMP)
1.26    skrll 		dumpsys();
1.26    skrll
1.26    skrll 	splx(s);
1.26    skrll #endif
1.26    skrll
1.26    skrll 	pmf_system_shutdown(boothowto);
1.26    skrll
1.26    skrll 	/* Say NO to interrupts for good */
1.26    skrll 	splhigh();
1.26    skrll
1.26    skrll 	/* Run any shutdown hooks */
1.26    skrll 	doshutdownhooks();
1.26    skrll
1.26    skrll 	/* Make sure IRQ's are disabled */
1.26    skrll 	DISABLE_INTERRUPTS();
1.26    skrll
1.27    skrll 	if (howto & RB_HALT) {
1.27    skrll 		printf("\n");
1.27    skrll 		printf("The operating system has halted.\n");
1.27    skrll 		printf("Please press any key to reboot.\n\n");
1.27    skrll 		cnpollc(1);	/* for proper keyboard command handling */
1.27    skrll 		if (cngetc() == 0) {
1.27    skrll 			/* no console attached, so just hlt */
1.27    skrll 			printf("No keyboard - cannot reboot after all.\n");
1.27    skrll 			goto spin;
1.27    skrll 		}
1.27    skrll 		cnpollc(0);
1.27    skrll 	}
1.27    skrll
1.27    skrll 	printf("rebooting...\n");
1.27    skrll
1.26    skrll 	sbi_system_reset(SBI_RESET_TYPE_COLDREBOOT, SBI_RESET_REASON_NONE);
1.27    skrll spin:
 1.1     matt 	for (;;) {
1.26    skrll 		asm volatile("wfi" ::: "memory");
 1.1     matt 	}
1.26    skrll 	/* NOTREACHED */
 1.1     matt }
 1.1     matt
 1.1     matt void
 1.1     matt cpu_dumpconf(void)
 1.1     matt {
 1.1     matt 	// TBD!!
 1.1     matt }
 1.1     matt
1.26    skrll
1.26    skrll int
1.26    skrll cpu_lwp_setprivate(lwp_t *l, void *addr)
1.26    skrll {
1.26    skrll 	struct trapframe * const tf = lwp_trapframe(l);
1.26    skrll
1.26    skrll 	tf->tf_reg[_REG_TP] = (register_t)addr;
1.26    skrll
1.26    skrll 	return 0;
1.26    skrll }
1.26    skrll
1.26    skrll
 1.1     matt void
 1.1     matt cpu_startup(void)
 1.1     matt {
 1.1     matt 	vaddr_t minaddr, maxaddr;
1.26    skrll 	char pbuf[10];	/* "999999 MB" -- But Sv39 is max 512GB */
 1.1     matt
 1.1     matt 	/*
 1.1     matt 	 * Good {morning,afternoon,evening,night}.
 1.1     matt 	 */
 1.1     matt 	printf("%s%s", copyright, version);
 1.1     matt 	format_bytes(pbuf, sizeof(pbuf), ctob(physmem));
 1.1     matt 	printf("total memory = %s\n", pbuf);
 1.1     matt
 1.1     matt 	minaddr = 0;
 1.1     matt 	/*
 1.1     matt 	 * Allocate a submap for physio.
 1.1     matt 	 */
 1.1     matt 	phys_map = uvm_km_suballoc(kernel_map, &minaddr, &maxaddr,
 1.1     matt 	    VM_PHYS_SIZE, 0, FALSE, NULL);
 1.1     matt
1.11       ad 	format_bytes(pbuf, sizeof(pbuf), ptoa(uvm_availmem(false)));
 1.1     matt 	printf("avail memory = %s\n", pbuf);
1.26    skrll
1.29    skrll #ifdef MULTIPROCESSOR
1.29    skrll 	kcpuset_create(&cpus_halted, true);
1.29    skrll 	KASSERT(cpus_halted != NULL);
1.29    skrll
1.29    skrll 	kcpuset_create(&cpus_hatched, true);
1.29    skrll 	KASSERT(cpus_hatched != NULL);
1.29    skrll
1.29    skrll 	kcpuset_create(&cpus_paused, true);
1.29    skrll 	KASSERT(cpus_paused != NULL);
1.29    skrll
1.29    skrll 	kcpuset_create(&cpus_resumed, true);
1.29    skrll 	KASSERT(cpus_resumed != NULL);
1.29    skrll
1.29    skrll 	kcpuset_create(&cpus_running, true);
1.29    skrll 	KASSERT(cpus_running != NULL);
1.29    skrll
1.34    skrll 	kcpuset_set(cpus_hatched, cpu_index(curcpu()));
1.34    skrll 	kcpuset_set(cpus_running, cpu_index(curcpu()));
1.29    skrll #endif
1.29    skrll
1.26    skrll 	fdtbus_intr_init();
1.31      rin
1.31      rin 	fdt_setup_rndseed();
1.31      rin 	fdt_setup_efirng();
1.26    skrll }
1.26    skrll
1.26    skrll static void
1.26    skrll riscv_add_memory(const struct fdt_memory *m, void *arg)
1.26    skrll {
1.26    skrll 	paddr_t first = atop(m->start);
1.26    skrll 	paddr_t last = atop(m->end);
1.26    skrll 	int freelist = VM_FREELIST_DEFAULT;
1.26    skrll
1.26    skrll 	VPRINTF("adding %#16" PRIxPADDR " - %#16" PRIxPADDR"  to freelist %d\n",
1.26    skrll 	    m->start, m->end, freelist);
1.26    skrll
1.26    skrll 	uvm_page_physload(first, last, first, last, freelist);
1.26    skrll 	physmem += last - first;
1.26    skrll }
1.26    skrll
1.26    skrll
1.26    skrll static void
1.26    skrll cpu_kernel_vm_init(paddr_t memory_start, paddr_t memory_end)
1.26    skrll {
1.26    skrll 	extern char __kernel_text[];
1.26    skrll 	extern char _end[];
1.26    skrll
1.26    skrll 	vaddr_t kernstart = trunc_page((vaddr_t)__kernel_text);
1.26    skrll 	vaddr_t kernend = round_page((vaddr_t)_end);
1.26    skrll 	paddr_t kernstart_phys = KERN_VTOPHYS(kernstart);
1.26    skrll 	paddr_t kernend_phys = KERN_VTOPHYS(kernend);
1.26    skrll
1.26    skrll 	VPRINTF("%s: kernel phys start %#" PRIxPADDR " end %#" PRIxPADDR "\n",
1.26    skrll 	    __func__, kernstart_phys, kernend_phys);
1.26    skrll 	fdt_memory_remove_range(kernstart_phys,
1.26    skrll 	    kernend_phys - kernstart_phys);
1.26    skrll
1.26    skrll 	/*
1.26    skrll 	 * Don't give these pages to UVM.
1.26    skrll 	 *
1.26    skrll 	 * cpu_kernel_vm_init need to create proper tables then the following
1.26    skrll 	 * will be true.
1.26    skrll 	 *
1.26    skrll 	 * Now we have APs started the pages used for stacks and L1PT can
1.26    skrll 	 * be given to uvm
1.26    skrll 	 */
1.26    skrll 	extern char const __start__init_memory[];
1.26    skrll 	extern char const __stop__init_memory[] __weak;
1.32      mrg 	if (&__start__init_memory[0] != &__stop__init_memory[0]) {
1.26    skrll 		const paddr_t spa = KERN_VTOPHYS((vaddr_t)__start__init_memory);
1.26    skrll 		const paddr_t epa = KERN_VTOPHYS((vaddr_t)__stop__init_memory);
1.26    skrll
1.26    skrll 		VPRINTF("%s: init   phys start %#" PRIxPADDR
1.26    skrll 		    " end %#" PRIxPADDR "\n", __func__, spa, epa);
1.26    skrll 		fdt_memory_remove_range(spa, epa - spa);
1.26    skrll 	}
1.26    skrll
1.26    skrll #ifdef _LP64
1.26    skrll 	paddr_t pa = memory_start & ~XSEGOFSET;
1.26    skrll 	pmap_direct_base = RISCV_DIRECTMAP_START;
1.26    skrll 	extern pd_entry_t l2_pte[PAGE_SIZE / sizeof(pd_entry_t)];
1.26    skrll
1.26    skrll
1.26    skrll 	const vsize_t vshift = XSEGSHIFT;
1.26    skrll 	const vaddr_t pdetab_mask = PMAP_PDETABSIZE - 1;
1.26    skrll 	const vsize_t inc = 1UL << vshift;
1.26    skrll
1.26    skrll 	const vaddr_t sva = RISCV_DIRECTMAP_START + pa;
1.26    skrll 	const vaddr_t eva = RISCV_DIRECTMAP_END;
1.26    skrll 	const size_t sidx = (sva >> vshift) & pdetab_mask;
1.26    skrll 	const size_t eidx = (eva >> vshift) & pdetab_mask;
1.26    skrll
1.26    skrll 	/* Allocate gigapages covering all physical memory in the direct map. */
1.26    skrll 	for (size_t i = sidx; i < eidx && pa < memory_end; i++, pa += inc) {
1.26    skrll 		l2_pte[i] = PA_TO_PTE(pa) | PTE_KERN | PTE_HARDWIRED | PTE_RW;
1.26    skrll 		VPRINTF("dm:   %p :  %#" PRIxPADDR "\n", &l2_pte[i], l2_pte[i]);
1.26    skrll 	}
1.26    skrll #endif
1.26    skrll //	pt_dump(printf);
 1.1     matt }
 1.1     matt
1.18    skrll static void
1.18    skrll riscv_init_lwp0_uarea(void)
1.18    skrll {
1.18    skrll 	extern char lwp0uspace[];
1.18    skrll
1.18    skrll 	uvm_lwp_setuarea(&lwp0, (vaddr_t)lwp0uspace);
1.18    skrll 	memset(&lwp0.l_md, 0, sizeof(lwp0.l_md));
1.18    skrll 	memset(lwp_getpcb(&lwp0), 0, sizeof(struct pcb));
1.18    skrll
1.18    skrll 	struct trapframe *tf = (struct trapframe *)(lwp0uspace + USPACE) - 1;
1.26    skrll 	memset(tf, 0, sizeof(*tf));
1.18    skrll
1.18    skrll 	lwp0.l_md.md_utf = lwp0.l_md.md_ktf = tf;
1.18    skrll }
1.18    skrll
1.18    skrll
1.18    skrll static void
1.18    skrll riscv_print_memory(const struct fdt_memory *m, void *arg)
1.18    skrll {
1.18    skrll
1.18    skrll 	VPRINTF("FDT /memory @ 0x%" PRIx64 " size 0x%" PRIx64 "\n",
1.18    skrll 	    m->start, m->end - m->start);
1.18    skrll }
1.18    skrll
1.18    skrll
1.18    skrll static void
1.26    skrll parse_mi_bootargs(char *args)
1.18    skrll {
1.18    skrll 	int howto;
1.26    skrll 	bool found, start, skipping;
1.26    skrll
1.26    skrll 	if (args == NULL)
1.26    skrll 		return;
1.18    skrll
1.26    skrll 	start = true;
1.26    skrll 	skipping = false;
1.18    skrll 	for (char *cp = args; *cp; cp++) {
1.26    skrll 		/* check for "words" starting with a "-" only */
1.26    skrll 		if (start) {
1.26    skrll 			if (*cp == '-') {
1.26    skrll 				skipping = false;
1.26    skrll 			} else {
1.26    skrll 				skipping = true;
1.26    skrll 			}
1.26    skrll 			start = false;
1.26    skrll 			continue;
1.26    skrll 		}
1.26    skrll
1.26    skrll 		if (*cp == ' ') {
1.26    skrll 			start = true;
1.26    skrll 			skipping = false;
1.26    skrll 			continue;
1.26    skrll 		}
1.26    skrll
1.26    skrll 		if (skipping) {
1.18    skrll 			continue;
1.26    skrll 		}
1.18    skrll
1.26    skrll 		/* Check valid boot flags */
1.18    skrll 		howto = 0;
1.18    skrll 		BOOT_FLAG(*cp, howto);
1.18    skrll 		if (!howto)
1.18    skrll 			printf("bootflag '%c' not recognised\n", *cp);
1.18    skrll 		else
1.18    skrll 			boothowto |= howto;
1.18    skrll 	}
1.26    skrll
1.26    skrll 	found = optstr_get(args, "root", bootdevstr, sizeof(bootdevstr));
1.26    skrll 	if (found) {
1.26    skrll 		bootspec = bootdevstr;
1.26    skrll 	}
1.18    skrll }
1.18    skrll
1.18    skrll
 1.1     matt void
1.21    skrll init_riscv(register_t hartid, paddr_t dtb)
 1.1     matt {
 1.9  thorpej
1.18    skrll 	/* set temporally to work printf()/panic() even before consinit() */
1.18    skrll 	cn_tab = &earlycons;
1.18    skrll
1.18    skrll 	/* Load FDT */
1.21    skrll 	const vaddr_t dtbva = VM_KERNEL_DTB_BASE + (dtb & (NBSEG - 1));
1.21    skrll 	void *fdt_data = (void *)dtbva;
1.18    skrll 	int error = fdt_check_header(fdt_data);
1.18    skrll 	if (error != 0)
1.18    skrll 	    panic("fdt_check_header failed: %s", fdt_strerror(error));
1.18    skrll
1.18    skrll 	fdtbus_init(fdt_data);
1.18    skrll
1.18    skrll 	/* Lookup platform specific backend */
1.29    skrll 	const struct fdt_platform * const plat = fdt_platform_find();
1.18    skrll 	if (plat == NULL)
1.18    skrll 		panic("Kernel does not support this device");
1.18    skrll
1.18    skrll 	/* Early console may be available, announce ourselves. */
1.18    skrll 	VPRINTF("FDT<%p>\n", fdt_data);
1.18    skrll
1.30      rin 	boot_args = fdt_get_bootargs();
1.18    skrll
1.26    skrll 	VPRINTF("devmap %p\n", plat->fp_devmap());
1.26    skrll 	pmap_devmap_bootstrap(0, plat->fp_devmap());
1.26    skrll
1.26    skrll 	VPRINTF("bootstrap\n");
1.26    skrll 	plat->fp_bootstrap();
1.26    skrll
1.18    skrll 	/*
1.18    skrll 	 * If stdout-path is specified on the command line, override the
1.18    skrll 	 * value in /chosen/stdout-path before initializing console.
1.18    skrll 	 */
1.18    skrll 	VPRINTF("stdout\n");
1.26    skrll 	fdt_update_stdout_path(fdt_data, boot_args);
1.18    skrll
1.18    skrll 	/*
1.18    skrll 	 * Done making changes to the FDT.
1.18    skrll 	 */
1.18    skrll 	fdt_pack(fdt_data);
1.18    skrll
1.26    skrll 	const uint32_t dtbsize = round_page(fdt_totalsize(fdt_data));
1.26    skrll
1.26    skrll 	VPRINTF("fdt size %x/%x\n", dtbsize, fdt_totalsize(fdt_data));
1.26    skrll
1.18    skrll 	VPRINTF("consinit ");
1.18    skrll 	consinit();
1.18    skrll 	VPRINTF("ok\n");
1.18    skrll
1.18    skrll 	/* Talk to the user */
1.18    skrll 	printf("NetBSD/riscv (fdt) booting ...\n");
1.18    skrll
1.18    skrll #ifdef BOOT_ARGS
1.18    skrll 	char mi_bootargs[] = BOOT_ARGS;
1.26    skrll 	parse_mi_bootargs(mi_bootargs);
1.18    skrll #endif
1.18    skrll
1.18    skrll 	uint64_t memory_start, memory_end;
1.18    skrll 	fdt_memory_get(&memory_start, &memory_end);
1.26    skrll 	physical_start = memory_start;
1.26    skrll 	physical_end = memory_end;
1.18    skrll
1.18    skrll 	fdt_memory_foreach(riscv_print_memory, NULL);
1.18    skrll
1.18    skrll 	/* Cannot map memory above largest page number */
1.18    skrll 	const uint64_t maxppn = __SHIFTOUT_MASK(PTE_PPN) - 1;
1.18    skrll 	const uint64_t memory_limit = ptoa(maxppn);
1.18    skrll
1.18    skrll 	if (memory_end > memory_limit) {
1.18    skrll 		fdt_memory_remove_range(memory_limit, memory_end);
1.18    skrll 		memory_end = memory_limit;
1.18    skrll 	}
1.18    skrll
1.18    skrll 	uint64_t memory_size __unused = memory_end - memory_start;
1.18    skrll
1.18    skrll 	VPRINTF("%s: memory start %" PRIx64 " end %" PRIx64 " (len %"
1.18    skrll 	    PRIx64 ")\n", __func__, memory_start, memory_end, memory_size);
1.18    skrll
1.31      rin 	/* Parse ramdisk, rndseed, and firmware's RNG from EFI */
1.31      rin 	fdt_probe_initrd();
1.31      rin 	fdt_probe_rndseed();
1.31      rin 	fdt_probe_efirng();
1.31      rin
1.26    skrll 	fdt_memory_remove_reserved(memory_start, memory_end);
1.26    skrll
1.28    skrll 	fdt_memory_remove_range(dtb, dtbsize);
1.31      rin 	fdt_reserve_initrd();
1.31      rin 	fdt_reserve_rndseed();
1.31      rin 	fdt_reserve_efirng();
1.26    skrll
1.18    skrll 	/* Perform PT build and VM init */
1.26    skrll 	cpu_kernel_vm_init(memory_start, memory_end);
1.18    skrll
1.30      rin 	VPRINTF("bootargs: %s\n", boot_args);
1.18    skrll
1.26    skrll 	parse_mi_bootargs(boot_args);
1.26    skrll
1.26    skrll #ifdef DDB
1.26    skrll 	if (boothowto & RB_KDB) {
1.26    skrll 		printf("Entering DDB...\n");
1.26    skrll 		cpu_Debugger();
1.26    skrll 	}
1.26    skrll #endif
1.18    skrll
1.18    skrll 	extern char __kernel_text[];
1.18    skrll 	extern char _end[];
1.26    skrll //	extern char __data_start[];
1.26    skrll //	extern char __rodata_start[];
1.18    skrll
1.18    skrll 	vaddr_t kernstart = trunc_page((vaddr_t)__kernel_text);
1.18    skrll 	vaddr_t kernend = round_page((vaddr_t)_end);
1.18    skrll 	paddr_t kernstart_phys __unused = KERN_VTOPHYS(kernstart);
1.18    skrll 	paddr_t kernend_phys __unused = KERN_VTOPHYS(kernend);
1.18    skrll
1.18    skrll 	vaddr_t kernelvmstart;
1.18    skrll
1.18    skrll 	vaddr_t kernstart_mega __unused = MEGAPAGE_TRUNC(kernstart);
1.18    skrll 	vaddr_t kernend_mega = MEGAPAGE_ROUND(kernend);
1.18    skrll
1.18    skrll 	kernelvmstart = kernend_mega;
1.18    skrll
1.26    skrll #if 0
1.26    skrll #ifdef MODULAR
1.26    skrll #define MODULE_RESERVED_MAX	(1024 * 1024 * 128)
1.26    skrll #define MODULE_RESERVED_SIZE	(1024 * 1024 * 32)	/* good enough? */
1.26    skrll 	module_start = kernelvmstart;
1.26    skrll 	module_end = kernend_mega + MODULE_RESERVED_SIZE;
1.26    skrll 	if (module_end >= kernstart_mega + MODULE_RESERVED_MAX)
1.26    skrll 		module_end = kernstart_mega + MODULE_RESERVED_MAX;
1.26    skrll 	KASSERT(module_end > kernend_mega);
1.26    skrll 	kernelvmstart = module_end;
1.26    skrll #endif /* MODULAR */
1.26    skrll #endif
1.26    skrll 	KASSERT(kernelvmstart < VM_KERNEL_VM_BASE);
1.26    skrll
1.26    skrll 	kernelvmstart = VM_KERNEL_VM_BASE;
1.26    skrll
1.26    skrll 	/*
1.26    skrll 	 * msgbuf is allocated from the top of the last biggest memory block.
1.26    skrll 	 */
1.26    skrll 	paddr_t msgbufaddr = 0;
1.26    skrll
1.26    skrll #ifdef _LP64
1.26    skrll 	/* XXX check all ranges for last one with a big enough hole */
1.26    skrll 	msgbufaddr = memory_end - MSGBUFSIZE;
1.26    skrll 	KASSERT(msgbufaddr != 0);	/* no space for msgbuf */
1.26    skrll 	fdt_memory_remove_range(msgbufaddr, msgbufaddr + MSGBUFSIZE);
1.26    skrll 	msgbufaddr = RISCV_PA_TO_KVA(msgbufaddr);
1.26    skrll 	VPRINTF("msgbufaddr = %#lx\n", msgbufaddr);
1.26    skrll 	initmsgbuf((void *)msgbufaddr, MSGBUFSIZE);
1.26    skrll #endif
1.26    skrll
1.26    skrll 	KASSERT(msgbufaddr != 0);	/* no space for msgbuf */
1.26    skrll #ifdef _LP64
1.26    skrll 	initmsgbuf((void *)RISCV_PA_TO_KVA(msgbufaddr), MSGBUFSIZE);
1.26    skrll #endif
1.26    skrll
1.20   simonb #define	DPRINTF(v)	VPRINTF("%24s = 0x%16lx\n", #v, (unsigned long)v);
1.18    skrll
1.18    skrll 	VPRINTF("------------------------------------------\n");
1.18    skrll 	DPRINTF(kern_vtopdiff);
1.18    skrll 	DPRINTF(memory_start);
1.18    skrll 	DPRINTF(memory_end);
1.18    skrll 	DPRINTF(memory_size);
1.18    skrll 	DPRINTF(kernstart_phys);
1.18    skrll 	DPRINTF(kernend_phys)
1.26    skrll 	DPRINTF(msgbufaddr);
1.26    skrll //	DPRINTF(physical_end);
1.18    skrll 	DPRINTF(VM_MIN_KERNEL_ADDRESS);
1.18    skrll 	DPRINTF(kernstart_mega);
1.18    skrll 	DPRINTF(kernstart);
1.18    skrll 	DPRINTF(kernend);
1.18    skrll 	DPRINTF(kernend_mega);
1.26    skrll #if 0
1.26    skrll #ifdef MODULAR
1.26    skrll 	DPRINTF(module_start);
1.26    skrll 	DPRINTF(module_end);
1.26    skrll #endif
1.26    skrll #endif
1.18    skrll 	DPRINTF(VM_MAX_KERNEL_ADDRESS);
1.26    skrll #ifdef _LP64
1.26    skrll 	DPRINTF(pmap_direct_base);
1.26    skrll #endif
1.18    skrll 	VPRINTF("------------------------------------------\n");
1.18    skrll
1.18    skrll #undef DPRINTF
1.18    skrll
1.26    skrll 	uvm_md_init();
1.18    skrll
1.18    skrll 	/*
1.26    skrll 	 * pass memory pages to uvm
1.18    skrll 	 */
1.26    skrll 	physmem = 0;
1.26    skrll 	fdt_memory_foreach(riscv_add_memory, NULL);
1.26    skrll
1.26    skrll 	pmap_bootstrap(kernelvmstart, VM_MAX_KERNEL_ADDRESS);
1.26    skrll
1.26    skrll 	kasan_init();
1.26    skrll
1.26    skrll 	/* Finish setting up lwp0 on our end before we call main() */
1.26    skrll 	riscv_init_lwp0_uarea();
1.29    skrll
1.29    skrll
1.29    skrll 	error = 0;
1.29    skrll 	if ((boothowto & RB_MD1) == 0) {
1.29    skrll 		VPRINTF("mpstart\n");
1.29    skrll 		if (plat->fp_mpstart)
1.29    skrll 			error = plat->fp_mpstart();
1.29    skrll 	}
1.29    skrll 	if (error)
1.29    skrll 		printf("AP startup problems\n");
1.26    skrll }
1.26    skrll
1.26    skrll
1.26    skrll #ifdef _LP64
1.26    skrll static void
1.26    skrll pte_bits(void (*pr)(const char *, ...), pt_entry_t pte)
1.26    skrll {
1.26    skrll 	(*pr)("%c%c%c%c%c%c%c%c",
1.26    skrll 	    (pte & PTE_D) ? 'D' : '.',
1.26    skrll 	    (pte & PTE_A) ? 'A' : '.',
1.26    skrll 	    (pte & PTE_G) ? 'G' : '.',
1.26    skrll 	    (pte & PTE_U) ? 'U' : '.',
1.26    skrll 	    (pte & PTE_X) ? 'X' : '.',
1.26    skrll 	    (pte & PTE_W) ? 'W' : '.',
1.26    skrll 	    (pte & PTE_R) ? 'R' : '.',
1.26    skrll 	    (pte & PTE_V) ? 'V' : '.');
1.26    skrll }
1.26    skrll
1.26    skrll static void
1.26    skrll dump_ln_table(paddr_t pdp_pa, int topbit, int level, vaddr_t va,
1.26    skrll     void (*pr)(const char *, ...) __printflike(1, 2))
1.26    skrll {
1.26    skrll 	pd_entry_t *pdp = (void *)PMAP_DIRECT_MAP(pdp_pa);
1.26    skrll
1.26    skrll 	(*pr)("l%u     @  pa %#16" PRIxREGISTER "\n", level, pdp_pa);
1.26    skrll 	for (size_t i = 0; i < PAGE_SIZE / sizeof(pd_entry_t); i++) {
1.26    skrll 		pd_entry_t entry = pdp[i];
1.26    skrll
1.26    skrll 		if (topbit) {
1.26    skrll 			va = i << (PGSHIFT + level * SEGLENGTH);
1.26    skrll 			if (va & __BIT(topbit)) {
1.26    skrll 				va |= __BITS(63, topbit);
1.26    skrll 			}
1.26    skrll 		}
1.26    skrll 		if (entry != 0) {
1.26    skrll 			paddr_t pa = __SHIFTOUT(entry, PTE_PPN) << PGSHIFT;
1.26    skrll 			// check level PPN bits.
1.26    skrll 			if (PTE_ISLEAF_P(entry)) {
1.26    skrll 				(*pr)("l%u %3zu    va 0x%016lx  pa 0x%012lx - ",
1.26    skrll 				      level, i, va, pa);
1.26    skrll 				pte_bits(pr, entry);
1.26    skrll 				(*pr)("\n");
1.26    skrll 			} else {
1.26    skrll 				(*pr)("l%u %3zu    va 0x%016lx  -> 0x%012lx - ",
1.26    skrll 				      level, i, va, pa);
1.26    skrll 				pte_bits(pr, entry);
1.26    skrll 				(*pr)("\n");
1.26    skrll 				if (level == 0) {
1.26    skrll 					(*pr)("wtf\n");
1.26    skrll 					continue;
1.26    skrll 				}
1.26    skrll 				if (pte_pde_valid_p(entry))
1.26    skrll 					dump_ln_table(pa, 0, level - 1, va, pr);
1.26    skrll 			}
1.26    skrll 		}
1.26    skrll 		va += 1UL << (PGSHIFT + level * SEGLENGTH);
1.26    skrll 	}
1.26    skrll }
1.26    skrll
1.26    skrll void
1.26    skrll pt_dump(void (*pr)(const char *, ...) __printflike(1, 2))
1.26    skrll {
1.26    skrll 	const register_t satp = csr_satp_read();
1.26    skrll 	size_t topbit = sizeof(long) * NBBY - 1;
1.26    skrll
1.26    skrll #ifdef _LP64
1.26    skrll 	const paddr_t satp_pa = __SHIFTOUT(satp, SATP_PPN) << PGSHIFT;
1.26    skrll 	const uint8_t mode = __SHIFTOUT(satp, SATP_MODE);
1.26    skrll 	u_int level = 1;
1.26    skrll
1.26    skrll 	switch (mode) {
1.26    skrll 	case SATP_MODE_SV39:
1.26    skrll 	case SATP_MODE_SV48:
1.26    skrll 		topbit = (39 - 1) + (mode - 8) * SEGLENGTH;
1.26    skrll 		level = mode - 6;
1.26    skrll 		break;
1.26    skrll 	}
1.26    skrll #endif
1.26    skrll 	(*pr)("topbit = %zu\n", topbit);
1.18    skrll
1.26    skrll 	(*pr)("satp   = 0x%" PRIxREGISTER "\n", satp);
1.18    skrll #ifdef _LP64
1.26    skrll 	dump_ln_table(satp_pa, topbit, level, 0, pr);
1.18    skrll #endif
1.26    skrll }
1.29    skrll #endif
1.26    skrll
1.26    skrll void
1.26    skrll consinit(void)
1.26    skrll {
1.26    skrll 	static bool initialized = false;
1.26    skrll 	const struct fdt_console *cons = fdtbus_get_console();
1.26    skrll 	const struct fdt_platform *plat = fdt_platform_find();
1.18    skrll
1.26    skrll 	if (initialized || cons == NULL)
1.26    skrll 		return;
1.26    skrll
1.26    skrll 	u_int uart_freq = 0;
1.26    skrll 	extern struct bus_space riscv_generic_bs_tag;
1.26    skrll 	struct fdt_attach_args faa = {
1.26    skrll 		.faa_bst = &riscv_generic_bs_tag,
1.26    skrll 	};
1.26    skrll
1.26    skrll 	faa.faa_phandle = fdtbus_get_stdout_phandle();
1.26    skrll 	if (plat->fp_uart_freq != NULL)
1.26    skrll 		uart_freq = plat->fp_uart_freq();
1.18    skrll
1.26    skrll 	cons->consinit(&faa, uart_freq);
1.18    skrll
1.26    skrll 	initialized = true;
 1.1     matt }