src/cpu/x86/smm/smm_module_loader.c - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /*
  * This file is part of the coreboot project.
  *
  * Copyright (C) 2012 ChromeOS Authors
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License as published by
  * the Free Software Foundation; version 2 of the License.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301 USA
  */

 #include <string.h>
 #include <rmodule.h>
 #include <cpu/x86/smm.h>
 #include <cpu/x86/cache.h>
 #include <console/console.h>

 /*
  * Compoments that make up the SMRAM:
  * 1. Save state - the total save state memory used
  * 2. Stack - stacks for the CPUs in the SMM handler
  * 3. Stub - SMM stub code for calling into handler
  * 4. Handler - C-based SMM handler.
  *
  * The compoents are assumed to consist of one consecutive region.
  */

 /* These paramters are used by the SMM stub code. A pointer to the params
  * is also passed to the C-base handler. */
 struct smm_stub_params {
 	u32 stack_size;
 	u32 stack_top;
 	u32 c_handler;
 	u32 c_handler_arg;
 	struct smm_runtime runtime;
 } __attribute__ ((packed));

 /*
  * The stub is the entry point that sets up protected mode and stacks for each
  * cpu. It then calls into the SMM handler module. It is encoded as an rmodule.
  */
 extern unsigned char _binary_smmstub_start[];

 /* This is the SMM handler that the stub calls. It is encoded as an rmodule. */
 extern unsigned char _binary_smm_start[];

 /* Per cpu minimum stack size. */
 #define SMM_MINIMUM_STACK_SIZE 32

 /*
  * The smm_entry_ins consists of 3 bytes. It is used when staggering SMRAM entry
  * addresses across CPUs.
  *
  * 0xe9 <16-bit relative target> ; jmp <relative-offset>
  */
 struct smm_entry_ins {
 	char jmp_rel;
 	uint16_t rel16;
 } __attribute__ ((packed));

 /*
  * Place the entry instructions for num entries beginning at entry_start with
  * a given stride. The entry_start is the highest entry point's address. All
  * other entry points are stride size below the previous.
  */
 static void smm_place_jmp_instructions(void *entry_start, int stride, int num,
                                        void *jmp_target)
 {
 	int i;
 	char *cur;
 	struct smm_entry_ins entry = { .jmp_rel = 0xe9 };

 	/* Each entry point has an IP value of 0x8000. The SMBASE for each
 	 * cpu is different so the effective address of the entry instruction
 	 * is different. Therefore, the relative displacment for each entry
 	 * instruction needs to be updated to reflect the current effective
 	 * IP. Additionally, the IP result from the jmp instruction is
 	 * calculated using the next instruction's address so the size of
 	 * the jmp instruction needs to be taken into account. */
 	cur = entry_start;
 	for (i = 0; i < num; i++) {
 		uint32_t disp = (uint32_t)jmp_target;

 		disp -= sizeof(entry) + (uint32_t)cur;
 		printk(BIOS_DEBUG,
 		       "SMM Module: placing jmp sequence at %p rel16 0x%04x\n",
 		       cur, disp);
 		entry.rel16 = disp;
 		memcpy(cur, &entry, sizeof(entry));
 		cur -= stride;
 	}
 }

 /* Place stacks in base -> base + size region, but ensure the stacks don't
  * overlap the staggered entry points. */
 static void *smm_stub_place_stacks(char *base, int size,
                                    struct smm_loader_params *params)
 {
 	int total_stack_size;
 	char *stacks_top;

 	if (params->stack_top != NULL)
 		return params->stack_top;

 	/* If stack space is requested assume the space lives in the lower
 	 * half of SMRAM. */
 	total_stack_size = params->per_cpu_stack_size *
 	                   params->num_concurrent_stacks;

 	/* There has to be at least one stack user. */
 	if (params->num_concurrent_stacks < 1)
 		return NULL;

 	/* Total stack size cannot fit. */
 	if (total_stack_size > size)
 		return NULL;

 	/* Stacks extend down to SMBASE */
 	stacks_top = &base[total_stack_size];

 	return stacks_top;
 }

 /* Place the staggered entry points for each CPU. The entry points are
  * staggered by the per cpu SMM save state size extending down from
  * SMM_ENTRY_OFFSET. */
 static void smm_stub_place_staggered_entry_points(char *base,
 	const struct smm_loader_params *params, const struct rmodule *smm_stub)
 {
 	int stub_entry_offset;

 	stub_entry_offset = rmodule_entry_offset(smm_stub);

 	/* If there are staggered entry points or the stub is not located
 	 * at the SMM entry point then jmp instructionss need to be placed. */
 	if (params->num_concurrent_save_states > 1 || stub_entry_offset != 0) {
 		int num_entries;

 		base += SMM_ENTRY_OFFSET;
 		num_entries = params->num_concurrent_save_states;
 		/* Adjust beginning entry and number of entries down since
 		 * the initial entry point doesn't need a jump sequence. */
 		if (stub_entry_offset == 0) {
 			base -= params->per_cpu_save_state_size;
 			num_entries--;
 		}
 		smm_place_jmp_instructions(base,
 		                           params->per_cpu_save_state_size,
 		                           num_entries,
 		                           rmodule_entry(smm_stub));
 	}
 }

 /*
  * The stub setup code assumes it is completely contained within the
  * default SMRAM size (0x10000). There are potentially 3 regions to place
  * within the default SMRAM size:
  * 1. Save state areas
  * 2. Stub code
  * 3. Stack areas
  *
  * The save state and stack areas are treated as contiguous for the number of
  * concurrent areas requested. The save state always lives at the top of SMRAM
  * space, and the entry point is at offset 0x8000.
  */
 static int smm_module_setup_stub(void *smbase, struct smm_loader_params *params)
 {
 	int total_save_state_size;
 	int smm_stub_size;
 	int stub_entry_offset;
 	char *smm_stub_loc;
 	void *stacks_top;
 	int size;
 	char *base;
 	int i;
 	struct smm_stub_params *stub_params;
 	struct rmodule smm_stub;

 	base = smbase;
 	size = SMM_DEFAULT_SIZE;

 	/* The number of concurrent stacks cannot exceed CONFIG_MAX_CPUS. */
 	if (params->num_concurrent_stacks > CONFIG_MAX_CPUS)
 		return -1;

 	/* Fail if can't parse the smm stub rmodule. */
 	if (rmodule_parse(&_binary_smmstub_start, &smm_stub))
 		return -1;

 	/* Adjust remaining size to account for save state. */
 	total_save_state_size = params->per_cpu_save_state_size *
 	                        params->num_concurrent_save_states;
 	size -= total_save_state_size;

 	/* The save state size encroached over the first SMM entry point. */
 	if (size <= SMM_ENTRY_OFFSET)
 		return -1;

 	/* Need a minimum stack size and alignment. */
 	if (params->per_cpu_stack_size <= SMM_MINIMUM_STACK_SIZE ||
 	    (params->per_cpu_stack_size & 3) != 0)
 		return -1;

 	smm_stub_loc = NULL;
 	smm_stub_size = rmodule_memory_size(&smm_stub);
 	stub_entry_offset = rmodule_entry_offset(&smm_stub);

 	/* Assume the stub is always small enough to live within upper half of
 	 * SMRAM region after the save state space has been allocated. */
 	smm_stub_loc = &base[SMM_ENTRY_OFFSET];

 	/* Adjust for jmp instruction sequence. */
 	if (stub_entry_offset != 0) {
 		int entry_sequence_size = sizeof(struct smm_entry_ins);
 		/* Align up to 16 bytes. */
 		entry_sequence_size += 15;
 		entry_sequence_size &= ~15;
 		smm_stub_loc += entry_sequence_size;
 		smm_stub_size += entry_sequence_size;
 	}

 	/* Stub is too big to fit. */
 	if (smm_stub_size > (size - SMM_ENTRY_OFFSET))
 		return -1;

 	/* The stacks, if requested, live in the lower half of SMRAM space. */
 	size = SMM_ENTRY_OFFSET;

 	/* Ensure stacks don't encroach onto staggered SMM
 	 * entry points. The staggered entry points extend
 	 * below SMM_ENTRY_OFFSET by the number of concurrent
 	 * save states - 1 and save state size. */
 	if (params->num_concurrent_save_states > 1) {
 		size -= total_save_state_size;
 		size += params->per_cpu_save_state_size;
 	}

 	/* Place the stacks in the lower half of SMRAM. */
 	stacks_top = smm_stub_place_stacks(base, size, params);
 	if (stacks_top == NULL)
 		return -1;

 	/* Load the stub. */
 	if (rmodule_load(smm_stub_loc, &smm_stub))
 		return -1;

 	/* Place staggered entry points. */
 	smm_stub_place_staggered_entry_points(base, params, &smm_stub);

 	/* Setup the parameters for the stub code. */
 	stub_params = rmodule_parameters(&smm_stub);
 	stub_params->stack_top = (u32)stacks_top;
 	stub_params->stack_size = params->per_cpu_stack_size;
 	stub_params->c_handler = (u32)params->handler;
 	stub_params->c_handler_arg = (u32)params->handler_arg;
 	stub_params->runtime.smbase = (u32)smbase;
 	stub_params->runtime.save_state_size = params->per_cpu_save_state_size;

 	/* Initialize the APIC id to cpu number table to be 1:1 */
 	for (i = 0; i < params->num_concurrent_stacks; i++)
 		stub_params->runtime.apic_id_to_cpu[i] = i;

 	/* Allow the initiator to manipulate SMM stub parameters. */
 	params->runtime = &stub_params->runtime;

 	printk(BIOS_DEBUG, "SMM Module: stub loaded at %p. Will call %p(%p)\n",
 	       smm_stub_loc, params->handler, params->handler_arg);

 	return 0;
 }

 /*
  * smm_setup_relocation_handler assumes the callback is already loaded in
  * memory. i.e. Another SMM module isn't chained to the stub. The other
  * assumption is that the stub will be entered from the default SMRAM
  * location: 0x30000 -> 0x40000.
  */
 int smm_setup_relocation_handler(struct smm_loader_params *params)
 {
 	void *smram = (void *)SMM_DEFAULT_BASE;

 	/* There can't be more than 1 concurrent save state for the relocation
 	 * handler because all CPUs default to 0x30000 as SMBASE. */
 	if (params->num_concurrent_save_states > 1)
 		return -1;

 	/* A handler has to be defined to call for relocation. */
 	if (params->handler == NULL)
 		return -1;

 	/* Since the relocation handler always uses stack, adjust the number
 	 * of conccurent stack users to be CONFIG_MAX_CPUS. */
 	if (params->num_concurrent_stacks == 0)
 		params->num_concurrent_stacks = CONFIG_MAX_CPUS;

 	return smm_module_setup_stub(smram, params);
 }

 /* The SMM module is placed within the provided region in the following
  * manner:
  * +-----------------+ <- smram + size
  * |    stacks       |
  * +-----------------+ <- smram + size - total_stack_size
  * |      ...        |
  * +-----------------+ <- smram + handler_size + SMM_DEFAULT_SIZE
  * |    handler      |
  * +-----------------+ <- smram + SMM_DEFAULT_SIZE
  * |    stub code    |
  * +-----------------+ <- smram
  *
  * It should be noted that this algorithm will not work for
  * SMM_DEFAULT_SIZE SMRAM regions such as the A segment. This algorithm
  * expectes a region large enough to encompass the handler and stacks
  * as well as the SMM_DEFAULT_SIZE.
  */
 int smm_load_module(void *smram, int size, struct smm_loader_params *params)
 {
 	struct rmodule smm_mod;
 	int total_stack_size;
 	int handler_size;
 	int module_alignment;
 	int alignment_size;
 	char *base;

 	if (size <= SMM_DEFAULT_SIZE)
 		return -1;

 	/* Fail if can't parse the smm rmodule. */
 	if (rmodule_parse(&_binary_smm_start, &smm_mod))
 		return -1;

 	total_stack_size = params->per_cpu_stack_size *
 	                   params->num_concurrent_stacks;

 	/* Stacks start at the top of the region. */
 	base = smram;
 	base += size;
 	params->stack_top = base;

 	/* SMM module starts at offset SMM_DEFAULT_SIZE with the load alignment
 	 * taken into account. */
 	base = smram;
 	base += SMM_DEFAULT_SIZE;
 	handler_size = rmodule_memory_size(&smm_mod);
 	module_alignment = rmodule_load_alignment(&smm_mod);
 	alignment_size = module_alignment - ((u32)base % module_alignment);
 	if (alignment_size != module_alignment) {
 		handler_size += alignment_size;
 		base += alignment_size;
 	}

 	/* Does the required amount of memory exceed the SMRAM region size? */
 	if ((total_stack_size + handler_size + SMM_DEFAULT_SIZE) > size)
 		return -1;

 	if (rmodule_load(base, &smm_mod))
 		return -1;

 	params->handler = rmodule_entry(&smm_mod);
 	params->handler_arg = rmodule_parameters(&smm_mod);

 	return smm_module_setup_stub(smram, params);
 }
	/*
	* This file is part of the coreboot project.
	*
	* Copyright (C) 2012 ChromeOS Authors
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License as published by
	* the Free Software Foundation; version 2 of the License.
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
	*/

	#include <string.h>
	#include <rmodule.h>
	#include <cpu/x86/smm.h>
	#include <cpu/x86/cache.h>
	#include <console/console.h>

	/*
	* Compoments that make up the SMRAM:
	* 1. Save state - the total save state memory used
	* 2. Stack - stacks for the CPUs in the SMM handler
	* 3. Stub - SMM stub code for calling into handler
	* 4. Handler - C-based SMM handler.
	*
	* The compoents are assumed to consist of one consecutive region.
	*/

	/* These paramters are used by the SMM stub code. A pointer to the params
	* is also passed to the C-base handler. */
	struct smm_stub_params {
	u32 stack_size;
	u32 stack_top;
	u32 c_handler;
	u32 c_handler_arg;
	struct smm_runtime runtime;
	} __attribute__ ((packed));

	/*
	* The stub is the entry point that sets up protected mode and stacks for each
	* cpu. It then calls into the SMM handler module. It is encoded as an rmodule.
	*/
	extern unsigned char _binary_smmstub_start[];

	/* This is the SMM handler that the stub calls. It is encoded as an rmodule. */
	extern unsigned char _binary_smm_start[];

	/* Per cpu minimum stack size. */
	#define SMM_MINIMUM_STACK_SIZE 32

	/*
	* The smm_entry_ins consists of 3 bytes. It is used when staggering SMRAM entry
	* addresses across CPUs.
	*
	* 0xe9 <16-bit relative target> ; jmp <relative-offset>
	*/
	struct smm_entry_ins {
	char jmp_rel;
	uint16_t rel16;
	} __attribute__ ((packed));

	/*
	* Place the entry instructions for num entries beginning at entry_start with
	* a given stride. The entry_start is the highest entry point's address. All
	* other entry points are stride size below the previous.
	*/
	static void smm_place_jmp_instructions(void *entry_start, int stride, int num,
	void *jmp_target)
	{
	int i;
	char *cur;
	struct smm_entry_ins entry = { .jmp_rel = 0xe9 };

	/* Each entry point has an IP value of 0x8000. The SMBASE for each
	* cpu is different so the effective address of the entry instruction
	* is different. Therefore, the relative displacment for each entry
	* instruction needs to be updated to reflect the current effective
	* IP. Additionally, the IP result from the jmp instruction is
	* calculated using the next instruction's address so the size of
	* the jmp instruction needs to be taken into account. */
	cur = entry_start;
	for (i = 0; i < num; i++) {
	uint32_t disp = (uint32_t)jmp_target;

	disp -= sizeof(entry) + (uint32_t)cur;
	printk(BIOS_DEBUG,
	"SMM Module: placing jmp sequence at %p rel16 0x%04x\n",
	cur, disp);
	entry.rel16 = disp;
	memcpy(cur, &entry, sizeof(entry));
	cur -= stride;
	}
	}

	/* Place stacks in base -> base + size region, but ensure the stacks don't
	* overlap the staggered entry points. */
	static void smm_stub_place_stacks(char base, int size,
	struct smm_loader_params *params)
	{
	int total_stack_size;
	char *stacks_top;

	if (params->stack_top != NULL)
	return params->stack_top;

	/* If stack space is requested assume the space lives in the lower
	* half of SMRAM. */
	total_stack_size = params->per_cpu_stack_size *
	params->num_concurrent_stacks;

	/* There has to be at least one stack user. */
	if (params->num_concurrent_stacks < 1)
	return NULL;

	/* Total stack size cannot fit. */
	if (total_stack_size > size)
	return NULL;

	/* Stacks extend down to SMBASE */
	stacks_top = &base[total_stack_size];

	return stacks_top;
	}

	/* Place the staggered entry points for each CPU. The entry points are
	* staggered by the per cpu SMM save state size extending down from
	* SMM_ENTRY_OFFSET. */
	static void smm_stub_place_staggered_entry_points(char *base,
	const struct smm_loader_params params, const struct rmodule smm_stub)
	{
	int stub_entry_offset;

	stub_entry_offset = rmodule_entry_offset(smm_stub);

	/* If there are staggered entry points or the stub is not located
	* at the SMM entry point then jmp instructionss need to be placed. */
	if (params->num_concurrent_save_states > 1 \|\| stub_entry_offset != 0) {
	int num_entries;

	base += SMM_ENTRY_OFFSET;
	num_entries = params->num_concurrent_save_states;
	/* Adjust beginning entry and number of entries down since
	* the initial entry point doesn't need a jump sequence. */
	if (stub_entry_offset == 0) {
	base -= params->per_cpu_save_state_size;
	num_entries--;
	}
	smm_place_jmp_instructions(base,
	params->per_cpu_save_state_size,
	num_entries,
	rmodule_entry(smm_stub));
	}
	}

	/*
	* The stub setup code assumes it is completely contained within the
	* default SMRAM size (0x10000). There are potentially 3 regions to place
	* within the default SMRAM size:
	* 1. Save state areas
	* 2. Stub code
	* 3. Stack areas
	*
	* The save state and stack areas are treated as contiguous for the number of
	* concurrent areas requested. The save state always lives at the top of SMRAM
	* space, and the entry point is at offset 0x8000.
	*/
	static int smm_module_setup_stub(void smbase, struct smm_loader_params params)
	{
	int total_save_state_size;
	int smm_stub_size;
	int stub_entry_offset;
	char *smm_stub_loc;
	void *stacks_top;
	int size;
	char *base;
	int i;
	struct smm_stub_params *stub_params;
	struct rmodule smm_stub;

	base = smbase;
	size = SMM_DEFAULT_SIZE;

	/* The number of concurrent stacks cannot exceed CONFIG_MAX_CPUS. */
	if (params->num_concurrent_stacks > CONFIG_MAX_CPUS)
	return -1;

	/* Fail if can't parse the smm stub rmodule. */
	if (rmodule_parse(&_binary_smmstub_start, &smm_stub))
	return -1;

	/* Adjust remaining size to account for save state. */
	total_save_state_size = params->per_cpu_save_state_size *
	params->num_concurrent_save_states;
	size -= total_save_state_size;

	/* The save state size encroached over the first SMM entry point. */
	if (size <= SMM_ENTRY_OFFSET)
	return -1;

	/* Need a minimum stack size and alignment. */
	if (params->per_cpu_stack_size <= SMM_MINIMUM_STACK_SIZE \|\|
	(params->per_cpu_stack_size & 3) != 0)
	return -1;

	smm_stub_loc = NULL;
	smm_stub_size = rmodule_memory_size(&smm_stub);
	stub_entry_offset = rmodule_entry_offset(&smm_stub);

	/* Assume the stub is always small enough to live within upper half of
	* SMRAM region after the save state space has been allocated. */
	smm_stub_loc = &base[SMM_ENTRY_OFFSET];

	/* Adjust for jmp instruction sequence. */
	if (stub_entry_offset != 0) {
	int entry_sequence_size = sizeof(struct smm_entry_ins);
	/* Align up to 16 bytes. */
	entry_sequence_size += 15;
	entry_sequence_size &= ~15;
	smm_stub_loc += entry_sequence_size;
	smm_stub_size += entry_sequence_size;
	}

	/* Stub is too big to fit. */
	if (smm_stub_size > (size - SMM_ENTRY_OFFSET))
	return -1;

	/* The stacks, if requested, live in the lower half of SMRAM space. */
	size = SMM_ENTRY_OFFSET;

	/* Ensure stacks don't encroach onto staggered SMM
	* entry points. The staggered entry points extend
	* below SMM_ENTRY_OFFSET by the number of concurrent
	* save states - 1 and save state size. */
	if (params->num_concurrent_save_states > 1) {
	size -= total_save_state_size;
	size += params->per_cpu_save_state_size;
	}

	/* Place the stacks in the lower half of SMRAM. */
	stacks_top = smm_stub_place_stacks(base, size, params);
	if (stacks_top == NULL)
	return -1;

	/* Load the stub. */
	if (rmodule_load(smm_stub_loc, &smm_stub))
	return -1;

	/* Place staggered entry points. */
	smm_stub_place_staggered_entry_points(base, params, &smm_stub);

	/* Setup the parameters for the stub code. */
	stub_params = rmodule_parameters(&smm_stub);
	stub_params->stack_top = (u32)stacks_top;
	stub_params->stack_size = params->per_cpu_stack_size;
	stub_params->c_handler = (u32)params->handler;
	stub_params->c_handler_arg = (u32)params->handler_arg;
	stub_params->runtime.smbase = (u32)smbase;
	stub_params->runtime.save_state_size = params->per_cpu_save_state_size;

	/* Initialize the APIC id to cpu number table to be 1:1 */
	for (i = 0; i < params->num_concurrent_stacks; i++)
	stub_params->runtime.apic_id_to_cpu[i] = i;

	/* Allow the initiator to manipulate SMM stub parameters. */
	params->runtime = &stub_params->runtime;

	printk(BIOS_DEBUG, "SMM Module: stub loaded at %p. Will call %p(%p)\n",
	smm_stub_loc, params->handler, params->handler_arg);

	return 0;
	}

	/*
	* smm_setup_relocation_handler assumes the callback is already loaded in
	* memory. i.e. Another SMM module isn't chained to the stub. The other
	* assumption is that the stub will be entered from the default SMRAM
	* location: 0x30000 -> 0x40000.
	*/
	int smm_setup_relocation_handler(struct smm_loader_params *params)
	{
	void smram = (void )SMM_DEFAULT_BASE;

	/* There can't be more than 1 concurrent save state for the relocation
	* handler because all CPUs default to 0x30000 as SMBASE. */
	if (params->num_concurrent_save_states > 1)
	return -1;

	/* A handler has to be defined to call for relocation. */
	if (params->handler == NULL)
	return -1;

	/* Since the relocation handler always uses stack, adjust the number
	* of conccurent stack users to be CONFIG_MAX_CPUS. */
	if (params->num_concurrent_stacks == 0)
	params->num_concurrent_stacks = CONFIG_MAX_CPUS;

	return smm_module_setup_stub(smram, params);
	}

	/* The SMM module is placed within the provided region in the following
	* manner:
	* +-----------------+ <- smram + size
	* \| stacks \|
	* +-----------------+ <- smram + size - total_stack_size
	* \| ... \|
	* +-----------------+ <- smram + handler_size + SMM_DEFAULT_SIZE
	* \| handler \|
	* +-----------------+ <- smram + SMM_DEFAULT_SIZE
	* \| stub code \|
	* +-----------------+ <- smram
	*
	* It should be noted that this algorithm will not work for
	* SMM_DEFAULT_SIZE SMRAM regions such as the A segment. This algorithm
	* expectes a region large enough to encompass the handler and stacks
	* as well as the SMM_DEFAULT_SIZE.
	*/
	int smm_load_module(void smram, int size, struct smm_loader_params params)
	{
	struct rmodule smm_mod;
	int total_stack_size;
	int handler_size;
	int module_alignment;
	int alignment_size;
	char *base;

	if (size <= SMM_DEFAULT_SIZE)
	return -1;

	/* Fail if can't parse the smm rmodule. */
	if (rmodule_parse(&_binary_smm_start, &smm_mod))
	return -1;

	total_stack_size = params->per_cpu_stack_size *
	params->num_concurrent_stacks;

	/* Stacks start at the top of the region. */
	base = smram;
	base += size;
	params->stack_top = base;

	/* SMM module starts at offset SMM_DEFAULT_SIZE with the load alignment
	* taken into account. */
	base = smram;
	base += SMM_DEFAULT_SIZE;
	handler_size = rmodule_memory_size(&smm_mod);
	module_alignment = rmodule_load_alignment(&smm_mod);
	alignment_size = module_alignment - ((u32)base % module_alignment);
	if (alignment_size != module_alignment) {
	handler_size += alignment_size;
	base += alignment_size;
	}

	/* Does the required amount of memory exceed the SMRAM region size? */
	if ((total_stack_size + handler_size + SMM_DEFAULT_SIZE) > size)
	return -1;

	if (rmodule_load(base, &smm_mod))
	return -1;

	params->handler = rmodule_entry(&smm_mod);
	params->handler_arg = rmodule_parameters(&smm_mod);

	return smm_module_setup_stub(smram, params);
	}