evbmips/sbmips/sb1250_icu.c

1.1  mrg /* $NetBSD: sb1250_icu.c,v 1.1 2017/07/24 08:56:29 mrg Exp $ */
1.1  mrg
1.1  mrg /*
1.1  mrg  * Copyright 2000, 2001
1.1  mrg  * Broadcom Corporation. All rights reserved.
1.1  mrg  *
1.1  mrg  * This software is furnished under license and may be used and copied only
1.1  mrg  * in accordance with the following terms and conditions.  Subject to these
1.1  mrg  * conditions, you may download, copy, install, use, modify and distribute
1.1  mrg  * modified or unmodified copies of this software in source and/or binary
1.1  mrg  * form. No title or ownership is transferred hereby.
1.1  mrg  *
1.1  mrg  * 1) Any source code used, modified or distributed must reproduce and
1.1  mrg  *    retain this copyright notice and list of conditions as they appear in
1.1  mrg  *    the source file.
1.1  mrg  *
1.1  mrg  * 2) No right is granted to use any trade name, trademark, or logo of
1.1  mrg  *    Broadcom Corporation.  The "Broadcom Corporation" name may not be
1.1  mrg  *    used to endorse or promote products derived from this software
1.1  mrg  *    without the prior written permission of Broadcom Corporation.
1.1  mrg  *
1.1  mrg  * 3) THIS SOFTWARE IS PROVIDED "AS-IS" AND ANY EXPRESS OR IMPLIED
1.1  mrg  *    WARRANTIES, INCLUDING BUT NOT LIMITED TO, ANY IMPLIED WARRANTIES OF
1.1  mrg  *    MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR
1.1  mrg  *    NON-INFRINGEMENT ARE DISCLAIMED. IN NO EVENT SHALL BROADCOM BE LIABLE
1.1  mrg  *    FOR ANY DAMAGES WHATSOEVER, AND IN PARTICULAR, BROADCOM SHALL NOT BE
1.1  mrg  *    LIABLE FOR DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  mrg  *    CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  mrg  *    SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
1.1  mrg  *    BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
1.1  mrg  *    WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
1.1  mrg  *    OR OTHERWISE), EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1  mrg  */
1.1  mrg
1.1  mrg #include <sys/cdefs.h>
1.1  mrg __KERNEL_RCSID(0, "$NetBSD: sb1250_icu.c,v 1.1 2017/07/24 08:56:29 mrg Exp $");
1.1  mrg
1.1  mrg #define	__INTR_PRIVATE
1.1  mrg
1.1  mrg #include <sys/param.h>
1.1  mrg #include <sys/systm.h>
1.1  mrg #include <sys/cpu.h>
1.1  mrg #include <sys/device.h>
1.1  mrg #include <sys/evcnt.h>
1.1  mrg #include <sys/kmem.h>
1.1  mrg
1.1  mrg /* XXX for uvmexp */
1.1  mrg #include <uvm/uvm_extern.h>
1.1  mrg
1.1  mrg #include <mips/locore.h>
1.1  mrg
1.1  mrg #include <sbmips/cpuvar.h>
1.1  mrg #include <sbmips/systemsw.h>
1.1  mrg
1.1  mrg #include <mips/sibyte/include/sb1250_regs.h>
1.1  mrg #include <mips/sibyte/include/sb1250_int.h>
1.1  mrg #include <mips/sibyte/include/sb1250_scd.h>
1.1  mrg
1.1  mrg static const struct ipl_sr_map sb1250_ipl_sr_map = {
1.1  mrg     .sr_bits = {
1.1  mrg 	[IPL_NONE]	=	MIPS_INT_MASK_5,
1.1  mrg 	[IPL_SOFTCLOCK]	=	MIPS_SOFT_INT_MASK_0 | MIPS_INT_MASK_5,
1.1  mrg 	[IPL_SOFTBIO]	=	MIPS_SOFT_INT_MASK_0 | MIPS_INT_MASK_5,
1.1  mrg 	[IPL_SOFTNET]	=	MIPS_SOFT_INT_MASK | MIPS_INT_MASK_5,
1.1  mrg 	[IPL_SOFTSERIAL] =	MIPS_SOFT_INT_MASK | MIPS_INT_MASK_5,
1.1  mrg 	[IPL_VM]	=	MIPS_SOFT_INT_MASK | MIPS_INT_MASK_0
1.1  mrg 				    | MIPS_INT_MASK_5,
1.1  mrg 	[IPL_SCHED]	=	MIPS_SOFT_INT_MASK | MIPS_INT_MASK_0
1.1  mrg 			  	    | MIPS_INT_MASK_1 | MIPS_INT_MASK_5,
1.1  mrg 	[IPL_DDB]	=	MIPS_SOFT_INT_MASK | MIPS_INT_MASK_0
1.1  mrg 			  	    | MIPS_INT_MASK_1 | MIPS_INT_MASK_4
1.1  mrg 			  	    | MIPS_INT_MASK_5,
1.1  mrg 	[IPL_HIGH]	=	MIPS_INT_MASK,
1.1  mrg     },
1.1  mrg };
1.1  mrg
1.1  mrg /* imr values corresponding to each pin */
1.1  mrg static uint64_t ints_for_ipl[_IPL_N];
1.1  mrg
1.1  mrg struct sb1250_ihand {
1.1  mrg 	void	(*ih_fun)(void *, uint32_t, vaddr_t);
1.1  mrg 	void	*ih_arg;
1.1  mrg 	int	ih_ipl;
1.1  mrg };
1.1  mrg
1.1  mrg static struct sb1250_ihand sb1250_ihands[K_INT_SOURCES];
1.1  mrg
1.1  mrg #ifdef MULTIPROCESSOR
1.1  mrg static void sb1250_ipi_intr(void *, uint32_t, vaddr_t);
1.1  mrg #endif
1.1  mrg #define	SB1250_I_MAP(x)		(R_IMR_INTERRUPT_MAP_BASE + (x) * 8)
1.1  mrg
1.1  mrg #define	READ_REG(rp)		mips3_ld((register_t)(rp))
1.1  mrg #define	WRITE_REG(rp, val)	mips3_sd((register_t)(rp), (val))
1.1  mrg
1.1  mrg static void	sb1250_cpu_intr(int, vaddr_t, uint32_t);
1.1  mrg static void	*sb1250_intr_establish(u_int, u_int,
1.1  mrg 		    void (*fun)(void *, uint32_t, vaddr_t), void *);
1.1  mrg
1.1  mrg static const char sb1250_intr_names[K_INT_SOURCES][16] = {
1.1  mrg 	[K_INT_WATCHDOG_TIMER_0]	= "wdog0",
1.1  mrg 	[K_INT_WATCHDOG_TIMER_1]	= "wdog1",
1.1  mrg 	[K_INT_TIMER_0]			= "timer0",
1.1  mrg 	[K_INT_TIMER_1]			= "timer1",
1.1  mrg 	[K_INT_TIMER_2]			= "timer2",
1.1  mrg 	[K_INT_TIMER_3]			= "timer3",
1.1  mrg 	[K_INT_SMB_0]			= "smb0",
1.1  mrg 	[K_INT_SMB_1]			= "smb1",
1.1  mrg 	[K_INT_UART_0]			= "uart0",
1.1  mrg 	[K_INT_UART_1]			= "uart1",
1.1  mrg 	[K_INT_SER_0]			= "syncser0",
1.1  mrg 	[K_INT_SER_1]			= "syncser1",
1.1  mrg 	[K_INT_PCMCIA]			= "pcmcia",
1.1  mrg 	[K_INT_ADDR_TRAP]		= "addrtrap",
1.1  mrg 	[K_INT_PERF_CNT]		= "perfcnt",
1.1  mrg 	[K_INT_TRACE_FREEZE]		= "tracefreeze",
1.1  mrg 	[K_INT_BAD_ECC]			= "bad ECC",
1.1  mrg 	[K_INT_COR_ECC]			= "corrected ECC",
1.1  mrg 	[K_INT_IO_BUS]			= "iobus",
1.1  mrg 	[K_INT_MAC_0]			= "mac0",
1.1  mrg 	[K_INT_MAC_1]			= "mac1",
1.1  mrg 	[K_INT_MAC_2]			= "mac2",
1.1  mrg 	[K_INT_DM_CH_0]			= "dmover0",
1.1  mrg 	[K_INT_DM_CH_1]			= "dmover1",
1.1  mrg 	[K_INT_DM_CH_2]			= "dmover2",
1.1  mrg 	[K_INT_DM_CH_3]			= "dmover3",
1.1  mrg 	[K_INT_MBOX_0]			= "mbox0",
1.1  mrg 	[K_INT_MBOX_1]			= "mbox1",
1.1  mrg 	[K_INT_MBOX_2]			= "mbox2",
1.1  mrg 	[K_INT_MBOX_3]			= "mbox3",
1.1  mrg 	[K_INT_CYCLE_CP0_INT]		= "zbccp0",
1.1  mrg 	[K_INT_CYCLE_CP1_INT]		= "zbccp1",
1.1  mrg 	[K_INT_GPIO_0]			= "gpio0",
1.1  mrg 	[K_INT_GPIO_1]			= "gpio1",
1.1  mrg 	[K_INT_GPIO_2]			= "gpio2",
1.1  mrg 	[K_INT_GPIO_3]			= "gpio3",
1.1  mrg 	[K_INT_GPIO_4]			= "gpio4",
1.1  mrg 	[K_INT_GPIO_5]			= "gpio5",
1.1  mrg 	[K_INT_GPIO_6]			= "gpio6",
1.1  mrg 	[K_INT_GPIO_7]			= "gpio7",
1.1  mrg 	[K_INT_GPIO_8]			= "gpio8",
1.1  mrg 	[K_INT_GPIO_9]			= "gpio9",
1.1  mrg 	[K_INT_GPIO_10]			= "gpio10",
1.1  mrg 	[K_INT_GPIO_11]			= "gpio11",
1.1  mrg 	[K_INT_GPIO_12]			= "gpio12",
1.1  mrg 	[K_INT_GPIO_13]			= "gpio13",
1.1  mrg 	[K_INT_GPIO_14]			= "gpio14",
1.1  mrg 	[K_INT_GPIO_15]			= "gpio15",
1.1  mrg 	[K_INT_LDT_FATAL]		= "ldt fatal",
1.1  mrg 	[K_INT_LDT_NONFATAL]		= "ldt nonfatal",
1.1  mrg 	[K_INT_LDT_SMI]			= "ldt smi",
1.1  mrg 	[K_INT_LDT_NMI]			= "ldt nmi",
1.1  mrg 	[K_INT_LDT_INIT]		= "ldt init",
1.1  mrg 	[K_INT_LDT_STARTUP]		= "ldt startup",
1.1  mrg 	[K_INT_LDT_EXT]			= "ldt ext",
1.1  mrg 	[K_INT_PCI_ERROR]		= "pci error",
1.1  mrg 	[K_INT_PCI_INTA]		= "pci inta",
1.1  mrg 	[K_INT_PCI_INTB]		= "pci intb",
1.1  mrg 	[K_INT_PCI_INTC]		= "pci intc",
1.1  mrg 	[K_INT_PCI_INTD]		= "pci intd",
1.1  mrg 	[K_INT_SPARE_2]			= "spare2",
1.1  mrg 	[K_INT_MAC_0_CH1]		= "mac0 ch1",
1.1  mrg 	[K_INT_MAC_1_CH1]		= "mac1 ch1",
1.1  mrg 	[K_INT_MAC_2_CH1]		= "mac2 ch1",
1.1  mrg };
1.1  mrg
1.1  mrg #ifdef MULTIPROCESSOR
1.1  mrg static void
1.1  mrg sb1250_lsw_cpu_init(struct cpu_info *ci)
1.1  mrg {
1.1  mrg 	struct cpu_softc * const cpu = ci->ci_softc;
1.1  mrg
1.1  mrg 	WRITE_REG(cpu->sb1cpu_imr_base + R_IMR_INTERRUPT_MASK, cpu->sb1cpu_imr_all);
1.1  mrg }
1.1  mrg
1.1  mrg static int
1.1  mrg sb1250_lsw_send_ipi(struct cpu_info *ci, int tag)
1.1  mrg {
1.1  mrg 	struct cpu_softc * const cpu = ci->ci_softc;
1.1  mrg 	const uint64_t mbox_mask = 1LLU << tag;
1.1  mrg
1.1  mrg 	if (cpus_running & (1 << cpu_index(ci)))
1.1  mrg 		WRITE_REG(cpu->sb1cpu_imr_base + R_IMR_MAILBOX_SET_CPU, mbox_mask);
1.1  mrg
1.1  mrg 	return 0;
1.1  mrg }
1.1  mrg
1.1  mrg static void
1.1  mrg sb1250_ipi_intr(void *arg, uint32_t status, vaddr_t pc)
1.1  mrg {
1.1  mrg 	struct cpu_info * const ci = curcpu();
1.1  mrg 	struct cpu_softc * const cpu = ci->ci_softc;
1.1  mrg 	uint64_t mbox_mask;
1.1  mrg
1.1  mrg 	ci->ci_data.cpu_nintr++;
1.1  mrg
1.1  mrg 	mbox_mask = READ_REG(cpu->sb1cpu_imr_base + R_IMR_MAILBOX_CPU);
1.1  mrg 	WRITE_REG(cpu->sb1cpu_imr_base + R_IMR_MAILBOX_CLR_CPU, mbox_mask);
1.1  mrg
1.1  mrg 	ipi_process(ci, mbox_mask);
1.1  mrg }
1.1  mrg #endif /* MULTIPROCESSOR */
1.1  mrg
1.1  mrg void
1.1  mrg sb1250_cpu_init(struct cpu_softc *cpu)
1.1  mrg {
1.1  mrg 	const char * const xname = device_xname(cpu->sb1cpu_dev);
1.1  mrg 	struct evcnt * evcnts = cpu->sb1cpu_intr_evcnts;
1.1  mrg
1.1  mrg 	cpu->sb1cpu_imr_base =
1.1  mrg 	    MIPS_PHYS_TO_KSEG1(A_IMR_MAPPER(cpu->sb1cpu_ci->ci_cpuid));
1.1  mrg #ifdef MULTIPROCESSOR
1.1  mrg 	cpu->sb1cpu_imr_all =
1.1  mrg 	    ~(M_INT_MBOX_0|M_INT_MBOX_1|M_INT_MBOX_2|M_INT_MBOX_3
1.1  mrg 	      |M_INT_WATCHDOG_TIMER_0|M_INT_WATCHDOG_TIMER_1);
1.1  mrg #else
1.1  mrg 	cpu->sb1cpu_imr_all = ~(M_INT_WATCHDOG_TIMER_0|M_INT_WATCHDOG_TIMER_1);
1.1  mrg #endif
1.1  mrg
1.1  mrg 	for (u_int i = 0; i < K_INT_SOURCES; i++, evcnts++) {
1.1  mrg 		WRITE_REG(cpu->sb1cpu_imr_base + SB1250_I_MAP(i), K_INT_MAP_I0);
1.1  mrg 		evcnt_attach_dynamic(evcnts, EVCNT_TYPE_INTR, NULL,
1.1  mrg 		    xname, sb1250_intr_names[i]);
1.1  mrg 	}
1.1  mrg #if 0
1.1  mrg 	WRITE_REG(cpu->sb1cpu_imr_base + SB1250_I_MAP(K_INT_WATCHDOG_TIMER_0), K_INT_MAP_NMI);
1.1  mrg 	WRITE_REG(cpu->sb1cpu_imr_base + SB1250_I_MAP(K_INT_WATCHDOG_TIMER_1), K_INT_MAP_NMI);
1.1  mrg #endif
1.1  mrg
1.1  mrg 	WRITE_REG(cpu->sb1cpu_imr_base + R_IMR_INTERRUPT_MASK, cpu->sb1cpu_imr_all);
1.1  mrg #ifdef MULTIPROCESSOR
1.1  mrg 	if (sb1250_ihands[K_INT_MBOX_0].ih_fun == NULL) {
1.1  mrg 		/*
1.1  mrg 		 * For now, deliver all IPIs at IPL_SCHED.  Eventually
1.1  mrg 		 * some will be at IPL_VM.
1.1  mrg 		 */
1.1  mrg 		for (int irq = K_INT_MBOX_0; irq <= K_INT_MBOX_3; irq++)
1.1  mrg 			sb1250_intr_establish(irq, IPL_SCHED,
1.1  mrg 			    sb1250_ipi_intr, NULL);
1.1  mrg 	}
1.1  mrg #endif /* MULTIPROCESSOR */
1.1  mrg }
1.1  mrg
1.1  mrg void
1.1  mrg sb1250_ipl_map_init(void)
1.1  mrg {
1.1  mrg 	ipl_sr_map = sb1250_ipl_sr_map;
1.1  mrg }
1.1  mrg
1.1  mrg void
1.1  mrg sb1250_icu_init(void)
1.1  mrg {
1.1  mrg 	const uint64_t imr_all = 0xffffffffffffffffULL;
1.1  mrg
1.1  mrg 	KASSERT(memcmp((const void *)&ipl_sr_map, (const void *)&sb1250_ipl_sr_map, sizeof(ipl_sr_map)) == 0);
1.1  mrg
1.1  mrg 	/* zero out the list of used interrupts/lines */
1.1  mrg 	memset(ints_for_ipl, 0, sizeof ints_for_ipl);
1.1  mrg 	memset(sb1250_ihands, 0, sizeof sb1250_ihands);
1.1  mrg
1.1  mrg 	systemsw.s_cpu_intr = sb1250_cpu_intr;
1.1  mrg 	systemsw.s_intr_establish = sb1250_intr_establish;
1.1  mrg
1.1  mrg #ifdef MULTIPROCESSOR
1.1  mrg 	/*
1.1  mrg 	 * Bits 27:24 (11:8 of G_SYS_PART) encode the number of CPUs present.
1.1  mrg 	 */
1.1  mrg 	u_int sys_part = G_SYS_PART(READ_REG(MIPS_PHYS_TO_KSEG1(A_SCD_SYSTEM_REVISION)));
1.1  mrg 	const u_int cpus = (sys_part >> 8) & 0xf;
1.1  mrg
1.1  mrg 	/*
1.1  mrg 	 * Allocate an evcnt structure for every possible interrupt on
1.1  mrg 	 * every possible CPU.
1.1  mrg 	 */
1.1  mrg 	vaddr_t imr = MIPS_PHYS_TO_KSEG1(A_IMR_CPU0_BASE + R_IMR_INTERRUPT_MASK);
1.1  mrg 	for (u_int i = 1; imr += IMR_REGISTER_SPACING, i < cpus; i++) {
1.1  mrg 		WRITE_REG(imr, imr_all);
1.1  mrg 	}
1.1  mrg #endif /* MULTIPROCESSOR */
1.1  mrg 	WRITE_REG(MIPS_PHYS_TO_KSEG1(A_IMR_CPU0_BASE + R_IMR_INTERRUPT_MASK),
1.1  mrg 	    imr_all);
1.1  mrg
1.1  mrg #ifdef MULTIPROCESSOR
1.1  mrg 	mips_locoresw.lsw_send_ipi = sb1250_lsw_send_ipi;
1.1  mrg 	mips_locoresw.lsw_cpu_init = sb1250_lsw_cpu_init;
1.1  mrg #endif /* MULTIPROCESSOR */
1.1  mrg }
1.1  mrg
1.1  mrg static void
1.1  mrg sb1250_cpu_intr(int ppl, vaddr_t pc, uint32_t status)
1.1  mrg {
1.1  mrg 	struct cpu_info * const ci = curcpu();
1.1  mrg 	struct cpu_softc * const cpu = ci->ci_softc;
1.1  mrg 	const vaddr_t imr_base = cpu->sb1cpu_imr_base;
1.1  mrg 	struct evcnt * const evcnts = cpu->sb1cpu_intr_evcnts;
1.1  mrg 	uint32_t pending;
1.1  mrg 	int ipl;
1.1  mrg
1.1  mrg 	ci->ci_data.cpu_nintr++;
1.1  mrg
1.1  mrg 	while (ppl < (ipl = splintr(&pending))) {
1.1  mrg 		splx(ipl);
1.1  mrg
1.1  mrg 		/* XXX do something if 5? */
1.1  mrg 		if (pending & MIPS_INT_MASK_5) {
1.1  mrg 			uint32_t cycles = mips3_cp0_count_read();
1.1  mrg 			mips3_cp0_compare_write(cycles - 1);
1.1  mrg 			/* just leave the bugger disabled */
1.1  mrg 		}
1.1  mrg
1.1  mrg 		uint64_t sstatus = ints_for_ipl[ipl];
1.1  mrg 		sstatus &= READ_REG(imr_base + R_IMR_INTERRUPT_SOURCE_STATUS);
1.1  mrg 		while (sstatus != 0) {
1.1  mrg #ifndef __mips_o32
1.1  mrg 			u_int n;
1.1  mrg 			__asm("dclz %0,%1" : "=r"(n) : "r"(sstatus));
1.1  mrg #else
1.1  mrg 			u_int n = (sstatus >> 32)
1.1  mrg 			    ?  0 + __builtin_clz(sstatus >> 32)
1.1  mrg 			    : 32 + __builtin_clz((uint32_t)sstatus);
1.1  mrg #endif
1.1  mrg 			u_int j = 63 - n;
1.1  mrg 			KASSERT(sstatus & (1ULL << j));
1.1  mrg 			sstatus ^= (1ULL << j);
1.1  mrg 			struct sb1250_ihand *ihp = &sb1250_ihands[j];
1.1  mrg 			KASSERT(ihp->ih_fun);
1.1  mrg 			(*ihp->ih_fun)(ihp->ih_arg, status, pc);
1.1  mrg 			evcnts[j].ev_count++;
1.1  mrg 		}
1.1  mrg 		(void) splhigh();
1.1  mrg 	}
1.1  mrg }
1.1  mrg
1.1  mrg static void *
1.1  mrg sb1250_intr_establish(u_int num, u_int ipl,
1.1  mrg     void (*fun)(void *, uint32_t, vaddr_t), void *arg)
1.1  mrg {
1.1  mrg 	struct cpu_softc * const cpu = curcpu()->ci_softc;
1.1  mrg 	struct sb1250_ihand * const ih = &sb1250_ihands[num];
1.1  mrg 	const int s = splhigh();
1.1  mrg
1.1  mrg 	if (num >= K_INT_SOURCES)
1.1  mrg 		panic("%s: invalid interrupt number (0x%x)", __func__, num);
1.1  mrg 	if (ipl >= _IPL_N || ipl < IPL_VM)
1.1  mrg 		panic("%s: invalid ipl %d", __func__, ipl);
1.1  mrg 	if (ih->ih_fun != NULL)
1.1  mrg 		panic("%s: cannot share sb1250 interrupts", __func__);
1.1  mrg
1.1  mrg 	ints_for_ipl[ipl] |= (1ULL << num);
1.1  mrg 	cpu->sb1cpu_imr_all &= ~(1ULL << num);
1.1  mrg
1.1  mrg 	ih->ih_fun = fun;
1.1  mrg 	ih->ih_arg = arg;
1.1  mrg 	ih->ih_ipl = ipl;
1.1  mrg
1.1  mrg 	if (num <= K_INT_WATCHDOG_TIMER_1)
1.1  mrg 		WRITE_REG(cpu->sb1cpu_imr_base + SB1250_I_MAP(num), K_INT_MAP_I4);
1.1  mrg 	else if (ipl > IPL_VM)
1.1  mrg 		WRITE_REG(cpu->sb1cpu_imr_base + SB1250_I_MAP(num), K_INT_MAP_I1);
1.1  mrg
1.1  mrg 	WRITE_REG(cpu->sb1cpu_imr_base + R_IMR_INTERRUPT_MASK, cpu->sb1cpu_imr_all);
1.1  mrg
1.1  mrg 	splx(s);
1.1  mrg
1.1  mrg 	return ih;
1.1  mrg }