X-Git-Url: https://git.saurik.com/apple/xnu.git/blobdiff_plain/43866e378188c25dd1e2208016ab3cbeb086ae6c..593a1d5fd87cdf5b46dd5fcb84467b432cea0f91:/osfmk/i386/commpage/commpage.c

diff --git a/osfmk/i386/commpage/commpage.c b/osfmk/i386/commpage/commpage.c
index 2c41d6662..b2bd5af50 100644
--- a/osfmk/i386/commpage/commpage.c
+++ b/osfmk/i386/commpage/commpage.c
@@ -1,16 +1,19 @@
 /*
- * Copyright (c) 2003 Apple Computer, Inc. All rights reserved.
+ * Copyright (c) 2003-2007 Apple Inc. All rights reserved.
  *
- * @APPLE_LICENSE_HEADER_START@
- * 
- * Copyright (c) 1999-2003 Apple Computer, Inc.  All Rights Reserved.
+ * @APPLE_OSREFERENCE_LICENSE_HEADER_START@
  * 
  * This file contains Original Code and/or Modifications of Original Code
  * as defined in and that are subject to the Apple Public Source License
  * Version 2.0 (the 'License'). You may not use this file except in
- * compliance with the License. Please obtain a copy of the License at
- * http://www.opensource.apple.com/apsl/ and read it before using this
- * file.
+ * compliance with the License. The rights granted to you under the License
+ * may not be used to create, or enable the creation or redistribution of,
+ * unlawful or unlicensed copies of an Apple operating system, or to
+ * circumvent, violate, or enable the circumvention or violation of, any
+ * terms of an Apple operating system software license agreement.
+ * 
+ * Please obtain a copy of the License at
+ * http://www.opensource.apple.com/apsl/ and read it before using this file.
  * 
  * The Original Code and all software distributed under the License are
  * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
@@ -20,16 +23,535 @@
  * Please see the License for the specific language governing rights and
  * limitations under the License.
  * 
- * @APPLE_LICENSE_HEADER_END@
+ * @APPLE_OSREFERENCE_LICENSE_HEADER_END@
  */
 
+/*
+ *	Here's what to do if you want to add a new routine to the comm page:
+ *
+ *		1. Add a definition for it's address in osfmk/i386/cpu_capabilities.h,
+ *		   being careful to reserve room for future expansion.
+ *
+ *		2. Write one or more versions of the routine, each with it's own
+ *		   commpage_descriptor.  The tricky part is getting the "special",
+ *		   "musthave", and "canthave" fields right, so that exactly one
+ *		   version of the routine is selected for every machine.
+ *		   The source files should be in osfmk/i386/commpage/.
+ *
+ *		3. Add a ptr to your new commpage_descriptor(s) in the "routines"
+ *		   array in osfmk/i386/commpage/commpage_asm.s.  There are two
+ *		   arrays, one for the 32-bit and one for the 64-bit commpage.
+ *
+ *		4. Write the code in Libc to use the new routine.
+ */
+
+#include <mach/mach_types.h>
+#include <mach/machine.h>
+#include <mach/vm_map.h>
+#include <i386/machine_routines.h>
+#include <i386/misc_protos.h>
+#include <i386/tsc.h>
+#include <i386/cpu_data.h>
 #include <machine/cpu_capabilities.h>
 #include <machine/commpage.h>
+#include <machine/pmap.h>
+#include <vm/vm_kern.h>
+#include <vm/vm_map.h>
+#include <ipc/ipc_port.h>
+
+#include <kern/page_decrypt.h>
+
+/* the lists of commpage routines are in commpage_asm.s  */
+extern	commpage_descriptor*	commpage_32_routines[];
+extern	commpage_descriptor*	commpage_64_routines[];
+
+/* translated commpage descriptors from commpage_sigs.c  */
+extern	commpage_descriptor sigdata_descriptor;
+extern	commpage_descriptor *ba_descriptors[];
+
+extern vm_map_t	commpage32_map;	// the shared submap, set up in vm init
+extern vm_map_t	commpage64_map;	// the shared submap, set up in vm init
+
+char	*commPagePtr32 = NULL;		// virtual addr in kernel map of 32-bit commpage
+char	*commPagePtr64 = NULL;		// ...and of 64-bit commpage
+int     _cpu_capabilities = 0;          // define the capability vector
+
+int	noVMX = 0;		/* if true, do not set kHasAltivec in ppc _cpu_capabilities */
+
+static uintptr_t next;			// next available byte in comm page
+static int     	cur_routine;		// comm page address of "current" routine
+static int     	matched;		// true if we've found a match for "current" routine
+
+static char    *commPagePtr;		// virtual addr in kernel map of commpage we are working on
+static size_t	commPageBaseOffset;	// add to 32-bit runtime address to get offset in commpage
+
+static	commpage_time_data	*time_data32 = NULL;
+static	commpage_time_data	*time_data64 = NULL;
+
+/* Allocate the commpage and add to the shared submap created by vm:
+ * 	1. allocate a page in the kernel map (RW)
+ *	2. wire it down
+ *	3. make a memory entry out of it
+ *	4. map that entry into the shared comm region map (R-only)
+ */
+
+static  void*
+commpage_allocate( 
+	vm_map_t	submap,			// commpage32_map or commpage_map64
+	size_t		area_used )		// _COMM_PAGE32_AREA_USED or _COMM_PAGE64_AREA_USED
+{
+	vm_offset_t	kernel_addr = 0;	// address of commpage in kernel map
+	vm_offset_t	zero = 0;
+	vm_size_t	size = area_used;	// size actually populated
+	vm_map_entry_t	entry;
+	ipc_port_t	handle;
+
+	if (submap == NULL)
+		panic("commpage submap is null");
+
+	if (vm_map(kernel_map,&kernel_addr,area_used,0,VM_FLAGS_ANYWHERE,NULL,0,FALSE,VM_PROT_ALL,VM_PROT_ALL,VM_INHERIT_NONE))
+		panic("cannot allocate commpage");
+
+	if (vm_map_wire(kernel_map,kernel_addr,kernel_addr+area_used,VM_PROT_DEFAULT,FALSE))
+		panic("cannot wire commpage");
+
+	/* 
+	 * Now that the object is created and wired into the kernel map, mark it so that no delay
+	 * copy-on-write will ever be performed on it as a result of mapping it into user-space.
+	 * If such a delayed copy ever occurred, we could remove the kernel's wired mapping - and
+	 * that would be a real disaster.
+	 *
+	 * JMM - What we really need is a way to create it like this in the first place.
+	 */
+	if (!vm_map_lookup_entry( kernel_map, vm_map_trunc_page(kernel_addr), &entry) || entry->is_sub_map)
+		panic("cannot find commpage entry");
+	entry->object.vm_object->copy_strategy = MEMORY_OBJECT_COPY_NONE;
+
+	if (mach_make_memory_entry( kernel_map,		// target map
+				    &size,		// size 
+				    kernel_addr,	// offset (address in kernel map)
+				    VM_PROT_ALL,	// map it RWX
+				    &handle,		// this is the object handle we get
+				    NULL ))		// parent_entry (what is this?)
+		panic("cannot make entry for commpage");
+
+	if (vm_map_64(	submap,				// target map (shared submap)
+			&zero,				// address (map into 1st page in submap)
+			area_used,			// size
+			0,				// mask
+			VM_FLAGS_FIXED,			// flags (it must be 1st page in submap)
+			handle,				// port is the memory entry we just made
+			0,                              // offset (map 1st page in memory entry)
+			FALSE,                          // copy
+			VM_PROT_READ|VM_PROT_EXECUTE,   // cur_protection (R-only in user map)
+			VM_PROT_READ|VM_PROT_EXECUTE,   // max_protection
+			VM_INHERIT_SHARE ))             // inheritance
+		panic("cannot map commpage");
+
+	ipc_port_release(handle);
+
+	return (void*) kernel_addr;                     // return address in kernel map
+}
+
+/* Get address (in kernel map) of a commpage field. */
+
+static void*
+commpage_addr_of(
+    int     addr_at_runtime )
+{
+    return  (void*) ((uintptr_t)commPagePtr + addr_at_runtime - commPageBaseOffset);
+}
+
+/* Determine number of CPUs on this system.  We cannot rely on
+ * machine_info.max_cpus this early in the boot.
+ */
+static int
+commpage_cpus( void )
+{
+	int cpus;
+
+	cpus = ml_get_max_cpus();                   // NB: this call can block
+
+	if (cpus == 0)
+		panic("commpage cpus==0");
+	if (cpus > 0xFF)
+		cpus = 0xFF;
+
+	return cpus;
+}
+
+/* Initialize kernel version of _cpu_capabilities vector (used by KEXTs.) */
+
+static void
+commpage_init_cpu_capabilities( void )
+{
+	int bits;
+	int cpus;
+	ml_cpu_info_t cpu_info;
+
+	bits = 0;
+	ml_cpu_get_info(&cpu_info);
+	
+	switch (cpu_info.vector_unit) {
+		case 8:
+			bits |= kHasSSE4_2;
+			/* fall thru */
+		case 7:
+			bits |= kHasSSE4_1;
+			/* fall thru */
+		case 6:
+			bits |= kHasSupplementalSSE3;
+			/* fall thru */
+		case 5:
+			bits |= kHasSSE3;
+			/* fall thru */
+		case 4:
+			bits |= kHasSSE2;
+			/* fall thru */
+		case 3:
+			bits |= kHasSSE;
+			/* fall thru */
+		case 2:
+			bits |= kHasMMX;
+		default:
+			break;
+	}
+	switch (cpu_info.cache_line_size) {
+		case 128:
+			bits |= kCache128;
+			break;
+		case 64:
+			bits |= kCache64;
+			break;
+		case 32:
+			bits |= kCache32;
+			break;
+		default:
+			break;
+	}
+	cpus = commpage_cpus();			// how many CPUs do we have
+
+	if (cpus == 1)
+		bits |= kUP;
+
+	bits |= (cpus << kNumCPUsShift);
+
+	bits |= kFastThreadLocalStorage;	// we use %gs for TLS
+
+	if (cpu_mode_is64bit())			// k64Bit means processor is 64-bit capable
+		bits |= k64Bit;
+
+	if (tscFreq <= SLOW_TSC_THRESHOLD)	/* is TSC too slow for _commpage_nanotime?  */
+		bits |= kSlow;
+
+	_cpu_capabilities = bits;		// set kernel version for use by drivers etc
+}
 
-int	_cpu_capabilities = 0;				/* define the capability vector */
+int
+_get_cpu_capabilities(void)
+{
+	return _cpu_capabilities;
+}
 
-void	commpage_populate( void ) {
+/* Copy data into commpage. */
 
-    /* no commpage on Intel yet */
+static void
+commpage_stuff(
+    int 	address,
+    const void 	*source,
+    int 	length	)
+{    
+    void	*dest = commpage_addr_of(address);
+    
+    if ((uintptr_t)dest < next)
+        panic("commpage overlap at address 0x%x, %p < 0x%lx", address, dest, next);
+    
+    bcopy(source,dest,length);
+    
+    next = ((uintptr_t)dest + length);
+}
+
+static void
+commpage_stuff_swap(
+	int	address,
+	void	*source,
+	int	length,
+	int	legacy )
+{
+	if ( legacy ) {
+		void *dest = commpage_addr_of(address);
+		dest = (void *)((uintptr_t) dest + _COMM_PAGE_SIGS_OFFSET);
+		switch (length) {
+			case 2:
+				OSWriteSwapInt16(dest, 0, *(uint16_t *)source);
+				break;
+			case 4:
+				OSWriteSwapInt32(dest, 0, *(uint32_t *)source);
+				break;
+			case 8:
+				OSWriteSwapInt64(dest, 0, *(uint64_t *)source);
+				break;
+		}
+	}
+}
+
+static void
+commpage_stuff2(
+	int	address,
+	void	*source,
+	int	length,
+	int	legacy )
+{
+	commpage_stuff_swap(address, source, length, legacy);
+	commpage_stuff(address, source, length);
+}
+
+/* Copy a routine into comm page if it matches running machine.
+ */
+static void
+commpage_stuff_routine(
+    commpage_descriptor	*rd	)
+{
+    int		must,cant;
+    
+    if (rd->commpage_address != cur_routine) {
+        if ((cur_routine!=0) && (matched==0))
+            panic("commpage no match for last, next address %08lx", rd->commpage_address);
+        cur_routine = rd->commpage_address;
+        matched = 0;
+    }
+    
+    must = _cpu_capabilities & rd->musthave;
+    cant = _cpu_capabilities & rd->canthave;
     
+    if ((must == rd->musthave) && (cant == 0)) {
+        if (matched)
+            panic("commpage multiple matches for address %08lx", rd->commpage_address);
+        matched = 1;
+        
+        commpage_stuff(rd->commpage_address,rd->code_address,rd->code_length);
+	}
+}
+
+/* Fill in the 32- or 64-bit commpage.  Called once for each.
+ * The 32-bit ("legacy") commpage has a bunch of stuff added to it
+ * for translated processes, some of which is byte-swapped.
+ */
+
+static void
+commpage_populate_one( 
+	vm_map_t	submap,		// commpage32_map or compage64_map
+	char **		kernAddressPtr,	// &commPagePtr32 or &commPagePtr64
+	size_t		area_used,	// _COMM_PAGE32_AREA_USED or _COMM_PAGE64_AREA_USED
+	size_t		base_offset,	// will become commPageBaseOffset
+	commpage_descriptor** commpage_routines, // list of routine ptrs for this commpage
+	boolean_t	legacy,		// true if 32-bit commpage
+	commpage_time_data** time_data,	// &time_data32 or &time_data64
+	const char*	signature )	// "commpage 32-bit" or "commpage 64-bit"
+{
+   	short   c2;
+	static double   two52 = 1048576.0 * 1048576.0 * 4096.0; // 2**52
+	static double   ten6 = 1000000.0;                       // 10**6
+	commpage_descriptor **rd;
+	short   version = _COMM_PAGE_THIS_VERSION;
+	int		swapcaps;
+
+	next = (uintptr_t) NULL;
+	cur_routine = 0;
+	commPagePtr = (char *)commpage_allocate( submap, (vm_size_t) area_used );
+	*kernAddressPtr = commPagePtr;				// save address either in commPagePtr32 or 64
+	commPageBaseOffset = base_offset;
+	
+	*time_data = commpage_addr_of( _COMM_PAGE_TIME_DATA_START );
+
+	/* Stuff in the constants.  We move things into the comm page in strictly
+	* ascending order, so we can check for overlap and panic if so.
+	*/
+	commpage_stuff(_COMM_PAGE_SIGNATURE,signature,strlen(signature));
+	commpage_stuff2(_COMM_PAGE_VERSION,&version,sizeof(short),legacy);
+	commpage_stuff(_COMM_PAGE_CPU_CAPABILITIES,&_cpu_capabilities,sizeof(int));
+
+	/* excuse our magic constants, we cannot include ppc/cpu_capabilities.h */
+	/* always set kCache32 and kDcbaAvailable */
+	swapcaps =  0x44;
+	if ( _cpu_capabilities & kUP )
+		swapcaps |= (kUP + (1 << kNumCPUsShift));
+	else
+		swapcaps |= 2 << kNumCPUsShift;	/* limit #cpus to 2 */
+	if ( ! noVMX )		/* if rosetta will be emulating altivec... */
+		swapcaps |= 0x101;	/* ...then set kHasAltivec and kDataStreamsAvailable too */
+	commpage_stuff_swap(_COMM_PAGE_CPU_CAPABILITIES, &swapcaps, sizeof(int), legacy);
+	c2 = 32;
+	commpage_stuff_swap(_COMM_PAGE_CACHE_LINESIZE,&c2,2,legacy);
+
+	if (_cpu_capabilities & kCache32)
+		c2 = 32;
+	else if (_cpu_capabilities & kCache64)
+		c2 = 64;
+	else if (_cpu_capabilities & kCache128)
+		c2 = 128;
+	commpage_stuff(_COMM_PAGE_CACHE_LINESIZE,&c2,2);
+
+	if ( legacy ) {
+		commpage_stuff2(_COMM_PAGE_2_TO_52,&two52,8,legacy);
+		commpage_stuff2(_COMM_PAGE_10_TO_6,&ten6,8,legacy);
+	}
+
+	for( rd = commpage_routines; *rd != NULL ; rd++ )
+		commpage_stuff_routine(*rd);
+
+	if (!matched)
+		panic("commpage no match on last routine");
+
+	if (next > (uintptr_t)_COMM_PAGE_END)
+		panic("commpage overflow: next = 0x%08lx, commPagePtr = 0x%08lx", next, (uintptr_t)commPagePtr);
+
+	if ( legacy ) {
+		next = (uintptr_t) NULL;
+		for( rd = ba_descriptors; *rd != NULL ; rd++ )
+			commpage_stuff_routine(*rd);
+
+		next = (uintptr_t) NULL;
+		commpage_stuff_routine(&sigdata_descriptor);
+	}	
+}
+
+
+/* Fill in commpages: called once, during kernel initialization, from the
+ * startup thread before user-mode code is running.
+ *
+ * See the top of this file for a list of what you have to do to add
+ * a new routine to the commpage.
+ */  
+
+void
+commpage_populate( void )
+{
+	commpage_init_cpu_capabilities();
+	
+	commpage_populate_one(	commpage32_map, 
+				&commPagePtr32,
+				_COMM_PAGE32_AREA_USED,
+				_COMM_PAGE32_BASE_ADDRESS,
+				commpage_32_routines, 
+				TRUE,			/* legacy (32-bit) commpage */
+				&time_data32,
+				"commpage 32-bit");
+	pmap_commpage32_init((vm_offset_t) commPagePtr32, _COMM_PAGE32_BASE_ADDRESS, 
+			   _COMM_PAGE32_AREA_USED/INTEL_PGBYTES);
+			   
+	time_data64 = time_data32;			/* if no 64-bit commpage, point to 32-bit */
+
+	if (_cpu_capabilities & k64Bit) {
+		commpage_populate_one(	commpage64_map, 
+					&commPagePtr64,
+					_COMM_PAGE64_AREA_USED,
+					_COMM_PAGE32_START_ADDRESS, /* because kernel is built 32-bit */
+					commpage_64_routines, 
+					FALSE,		/* not a legacy commpage */
+					&time_data64,
+					"commpage 64-bit");
+		pmap_commpage64_init((vm_offset_t) commPagePtr64, _COMM_PAGE64_BASE_ADDRESS, 
+				   _COMM_PAGE64_AREA_USED/INTEL_PGBYTES);
+	}
+
+	rtc_nanotime_init_commpage();
+}
+
+
+/* Update commpage nanotime information.  Note that we interleave
+ * setting the 32- and 64-bit commpages, in order to keep nanotime more
+ * nearly in sync between the two environments.
+ *
+ * This routine must be serialized by some external means, ie a lock.
+ */
+
+void
+commpage_set_nanotime(
+	uint64_t	tsc_base,
+	uint64_t	ns_base,
+	uint32_t	scale,
+	uint32_t	shift )
+{
+	commpage_time_data	*p32 = time_data32;
+	commpage_time_data	*p64 = time_data64;
+	static uint32_t	generation = 0;
+	uint32_t	next_gen;
+	
+	if (p32 == NULL)		/* have commpages been allocated yet? */
+		return;
+		
+	if ( generation != p32->nt_generation )
+		panic("nanotime trouble 1");	/* possibly not serialized */
+	if ( ns_base < p32->nt_ns_base )
+		panic("nanotime trouble 2");
+	if ((shift != 32) && ((_cpu_capabilities & kSlow)==0) )
+		panic("nanotime trouble 3");
+		
+	next_gen = ++generation;
+	if (next_gen == 0)
+		next_gen = ++generation;
+	
+	p32->nt_generation = 0;		/* mark invalid, so commpage won't try to use it */
+	p64->nt_generation = 0;
+	
+	p32->nt_tsc_base = tsc_base;
+	p64->nt_tsc_base = tsc_base;
+	
+	p32->nt_ns_base = ns_base;
+	p64->nt_ns_base = ns_base;
+	
+	p32->nt_scale = scale;
+	p64->nt_scale = scale;
+	
+	p32->nt_shift = shift;
+	p64->nt_shift = shift;
+	
+	p32->nt_generation = next_gen;	/* mark data as valid */
+	p64->nt_generation = next_gen;
+}
+
+
+/* Disable commpage gettimeofday(), forcing commpage to call through to the kernel.  */
+
+void
+commpage_disable_timestamp( void )
+{
+	time_data32->gtod_generation = 0;
+	time_data64->gtod_generation = 0;
+}
+
+
+/* Update commpage gettimeofday() information.  As with nanotime(), we interleave
+ * updates to the 32- and 64-bit commpage, in order to keep time more nearly in sync 
+ * between the two environments.
+ *
+ * This routine must be serializeed by some external means, ie a lock.
+ */
+ 
+ void
+ commpage_set_timestamp(
+	uint64_t	abstime,
+	uint64_t	secs )
+{
+	commpage_time_data	*p32 = time_data32;
+	commpage_time_data	*p64 = time_data64;
+	static uint32_t	generation = 0;
+	uint32_t	next_gen;
+	
+	next_gen = ++generation;
+	if (next_gen == 0)
+		next_gen = ++generation;
+	
+	p32->gtod_generation = 0;		/* mark invalid, so commpage won't try to use it */
+	p64->gtod_generation = 0;
+	
+	p32->gtod_ns_base = abstime;
+	p64->gtod_ns_base = abstime;
+	
+	p32->gtod_sec_base = secs;
+	p64->gtod_sec_base = secs;
+	
+	p32->gtod_generation = next_gen;	/* mark data as valid */
+	p64->gtod_generation = next_gen;
 }