/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2006 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _SYS_MACHTHREAD_H #define _SYS_MACHTHREAD_H #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #ifdef __cplusplus extern "C" { #endif #ifdef _ASM #define THREAD_REG %g7 /* pointer to current thread data */ /* * Get the processor implementation from the version register. */ #define GET_CPU_IMPL(out) \ rdpr %ver, out; \ srlx out, 32, out; \ sll out, 16, out; \ srl out, 16, out; #ifdef _STARFIRE /* * CPU_INDEX(r, scr) * Returns cpu id in r. * On Starfire, this is read from the Port Controller's Port ID * register in local space. * * Need to load the 64 bit address of the PC's PortID reg * using only one register. Kludge the 41 bits address constant to * be 32bits by shifting it 12 bits to the right first. */ #define LOCAL_PC_PORTID_ADDR_SRL12 0x1FFF4000 #define PC_PORT_ID 0xD0 #define CPU_INDEX(r, scr) \ rdpr %pstate, scr; \ andn scr, PSTATE_IE | PSTATE_AM, r; \ wrpr r, 0, %pstate; \ set LOCAL_PC_PORTID_ADDR_SRL12, r; \ sllx r, 12, r; \ or r, PC_PORT_ID, r; \ lduwa [r]ASI_IO, r; \ wrpr scr, 0, %pstate #elif defined(_OPL) /* * For OPL platform, we get CPU_INDEX from ASI_EIDR. */ #define CPU_INDEX(r, scr) \ ldxa [%g0]ASI_EIDR, r; \ and r, 0xfff, r #else /* _STARFIRE */ /* * UPA supports up to 32 devices while Safari supports up to * 1024 devices (utilizing the SSM protocol). Based upon the * value of NCPU, a 5- or 10-bit mask will be needed for * extracting the cpu id. */ #if NCPU > 32 #define CPU_MASK 0x3ff #else #define CPU_MASK 0x1f #endif /* NCPU > 32 */ /* * CPU_INDEX(r, scr) * Returns cpu id in r. * For UPA based systems, the cpu id corresponds to the mid field in * the UPA config register. For Safari based machines, the cpu id * corresponds to the aid field in the Safari config register. * * XXX - scr reg is not used here. */ #define CPU_INDEX(r, scr) \ ldxa [%g0]ASI_UPA_CONFIG, r; \ srlx r, 17, r; \ and r, CPU_MASK, r #endif /* _STARFIRE */ /* * Given a cpu id extract the appropriate word * in the cpuset mask for this cpu id. */ #if CPUSET_SIZE > CLONGSIZE #define CPU_INDEXTOSET(base, index, scr) \ srl index, BT_ULSHIFT, scr; \ and index, BT_ULMASK, index; \ sll scr, CLONGSHIFT, scr; \ add base, scr, base #else #define CPU_INDEXTOSET(base, index, scr) #endif /* CPUSET_SIZE */ /* * Assembly macro to find address of the current CPU. * Used when coming in from a user trap - cannot use THREAD_REG. * Args are destination register and one scratch register. */ #define CPU_ADDR(reg, scr) \ .global cpu; \ CPU_INDEX(scr, reg); \ sll scr, CPTRSHIFT, scr; \ set cpu, reg; \ ldn [reg + scr], reg #define CINT64SHIFT 3 /* * Assembly macro to find the physical address of the current CPU. * All memory references using VA must be limited to nucleus * memory to avoid any MMU side effect. */ #define CPU_PADDR(reg, scr) \ .global cpu_pa; \ CPU_INDEX(scr, reg); \ sll scr, CINT64SHIFT, scr; \ set cpu_pa, reg; \ ldx [reg + scr], reg #endif /* _ASM */ /* * If a high level trap handler decides to call sys_trap() to execute some * base level code, context and other registers must be set to proper * values to run kernel. This is true for most part of the kernel, except * for user_rtt, a substantial part of which is executed with registers * ready to run user code. The following macro may be used to detect this * condition and handle it. Please note that, in general, we can't restart * arbitrary piece of code running at tl > 0; user_rtt is a special case * that can be handled. * * Entry condition: * * %tl = 2 * pstate.ag = 1 * * Register usage: * * scr1, scr2 - destroyed * normal %g5 and %g6 - destroyed * */ /* BEGIN CSTYLED */ #define RESET_USER_RTT_REGS(scr1, scr2, label) \ /* \ * do nothing if %tl != 2. this an attempt to stop this \ * piece of code from executing more than once before going \ * back to TL=0. more specifically, the changes we are doing \ * to %wstate, %canrestore and %otherwin can't be done more \ * than once before going to TL=0. note that it is okay to \ * execute this more than once if we restart at user_rtt and \ * come back from there. \ */ \ rdpr %tl, scr1; \ cmp scr1, 2; \ bne,a,pn %xcc, label; \ nop; \ /* \ * read tstate[2].%tpc. do nothing if it is not \ * between rtt_ctx_start and rtt_ctx_end. \ */ \ rdpr %tpc, scr1; \ set rtt_ctx_end, scr2; \ cmp scr1, scr2; \ bgu,a,pt %xcc, label; \ nop; \ set rtt_ctx_start, scr2; \ cmp scr1, scr2; \ blu,a,pt %xcc, label; \ nop; \ /* \ * pickup tstate[2].cwp \ */ \ rdpr %tstate, scr1; \ and scr1, TSTATE_CWP, scr1; \ /* \ * set tstate[1].cwp to tstate[2].cwp. fudge \ * tstate[1].tpc and tstate[1].tnpc to restart \ * user_rtt. \ */ \ wrpr %g0, 1, %tl; \ set TSTATE_KERN | TSTATE_IE, scr2; \ or scr1, scr2, scr2; \ wrpr %g0, scr2, %tstate; \ set user_rtt, scr1; \ wrpr %g0, scr1, %tpc; \ add scr1, 4, scr1; \ wrpr %g0, scr1, %tnpc; \ /* \ * restore %tl \ */ \ wrpr %g0, 2, %tl; \ /* \ * set %wstate \ */ \ rdpr %wstate, scr1; \ sllx scr1, WSTATE_SHIFT, scr1; \ wrpr scr1, WSTATE_K64, %wstate; \ /* \ * setup window registers \ * %cleanwin <-- nwin - 1 \ * %otherwin <-- %canrestore \ * %canrestore <-- 0 \ */ \ sethi %hi(nwin_minus_one), scr1; \ ld [scr1 + %lo(nwin_minus_one)], scr1; \ wrpr %g0, scr1, %cleanwin; \ rdpr %canrestore, scr1; \ wrpr %g0, scr1, %otherwin; \ wrpr %g0, 0, %canrestore; \ /* \ * set THREAD_REG, as we have restored user \ * registers in user_rtt. we trash %g5 and %g6 \ * in the process. \ */ \ rdpr %pstate, scr1; \ wrpr scr1, PSTATE_AG, %pstate; \ /* \ * using normal globals now \ */ \ CPU_ADDR(%g5, %g6); \ ldn [%g5 + CPU_THREAD], %g6; \ mov %g6, THREAD_REG; \ rdpr %pstate, %g5; \ wrpr %g5, PSTATE_AG, %pstate; \ /* \ * back to alternate globals. \ * set PCONTEXT to run kernel. \ * no need to demap I/DTLB as we \ * never went back to user mode. \ */ \ mov MMU_PCONTEXT, scr1; \ sethi %hi(kcontextreg), scr2; \ ldx [scr2 + %lo(kcontextreg)], scr2; \ stxa scr2, [scr1]ASI_MMU_CTX; \ sethi %hi(FLUSH_ADDR), scr1; \ flush scr1; /* END CSTYLED */ #ifdef __cplusplus } #endif #endif /* _SYS_MACHTHREAD_H */