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hafnium / hafnium / b1a6d0d0b1cabae13482039023028a6a7a92787d / . / test / vmapi / primary_with_secondaries / services / memory.c
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/*
* Copyright 2018 The Hafnium Authors.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* https://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "hf/arch/vm/interrupts.h"
#include "hf/mm.h"
#include "hf/std.h"
#include "vmapi/hf/call.h"
#include "primary_with_secondary.h"
#include "test/hftest.h"
#include "test/vmapi/exception_handler.h"
#include "test/vmapi/spci.h"
alignas(PAGE_SIZE) static uint8_t page[PAGE_SIZE];
TEST_SERVICE(memory_increment)
{
/* Loop, writing message to the shared memory. */
for (;;) {
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
size_t i;
void *recv_buf = SERVICE_RECV_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
spci_vm_id_t sender = memory_region->sender;
EXPECT_EQ(ret.func, SPCI_MEM_SHARE_32);
ptr = (uint8_t *)constituents[0].address;
/* Check the memory was cleared. */
for (i = 0; i < PAGE_SIZE; ++i) {
ASSERT_EQ(ptr[i], 0);
}
/* Allow the memory to be populated. */
EXPECT_EQ(spci_yield().func, SPCI_SUCCESS_32);
/* Increment each byte of memory. */
for (i = 0; i < PAGE_SIZE; ++i) {
++ptr[i];
}
/* Signal completion and reset. */
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
spci_msg_send(hf_vm_get_id(), sender, sizeof(ptr), 0);
}
}
TEST_SERVICE(give_memory_and_fault)
{
void *send_buf = SERVICE_SEND_BUFFER();
/* Give memory to the primary. */
struct spci_memory_region_constituent constituents[] = {
{.address = (uint64_t)&page, .page_count = 1},
};
uint32_t msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), HF_PRIMARY_VM_ID, constituents,
ARRAY_SIZE(constituents), 0, SPCI_MEMORY_REGION_FLAG_CLEAR,
SPCI_MEMORY_RW_X, SPCI_MEMORY_NORMAL_MEM,
SPCI_MEMORY_CACHE_WRITE_BACK, SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_mem_donate(msg_size, msg_size, 0).func, SPCI_SUCCESS_32);
exception_setup(NULL, exception_handler_yield_data_abort);
/* Try using the memory that isn't valid unless it's been returned. */
page[16] = 123;
FAIL("Exception not generated by invalid access.");
}
TEST_SERVICE(lend_memory_and_fault)
{
void *send_buf = SERVICE_SEND_BUFFER();
/* Lend memory to the primary. */
struct spci_memory_region_constituent constituents[] = {
{.address = (uint64_t)&page, .page_count = 1},
};
uint32_t msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), HF_PRIMARY_VM_ID, constituents,
ARRAY_SIZE(constituents), 0, SPCI_MEMORY_REGION_FLAG_CLEAR,
SPCI_MEMORY_RW_X, SPCI_MEMORY_NORMAL_MEM,
SPCI_MEMORY_CACHE_WRITE_BACK, SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_mem_lend(msg_size, msg_size, 0).func, SPCI_SUCCESS_32);
exception_setup(NULL, exception_handler_yield_data_abort);
/* Try using the memory that isn't valid unless it's been returned. */
page[633] = 180;
FAIL("Exception not generated by invalid access.");
}
TEST_SERVICE(spci_memory_return)
{
exception_setup(NULL, exception_handler_yield_data_abort);
/* Loop, giving memory back to the sender. */
for (;;) {
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint32_t msg_size;
size_t i;
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region;
struct spci_memory_region_constituent *constituents;
/*
* The memory may have been sent in one of several different
* ways.
*/
EXPECT_TRUE(ret.func == SPCI_MEM_DONATE_32 ||
ret.func == SPCI_MEM_LEND_32 ||
ret.func == SPCI_MEM_SHARE_32);
memory_region = (struct spci_memory_region *)recv_buf;
constituents =
spci_memory_region_get_constituents(memory_region);
ptr = (uint8_t *)constituents[0].address;
/* Check that one has access to the shared region. */
for (i = 0; i < PAGE_SIZE; ++i) {
ptr[i]++;
}
/* Give the memory back and notify the sender. */
msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), memory_region->sender,
constituents, memory_region->constituent_count, 0, 0,
SPCI_MEMORY_RW_X, SPCI_MEMORY_NORMAL_MEM,
SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
EXPECT_EQ(spci_mem_donate(msg_size, msg_size, 0).func,
SPCI_SUCCESS_32);
/*
* Try and access the memory which will cause a fault unless the
* memory has been shared back again.
*/
ptr[0] = 123;
FAIL("Exception not generated by invalid access.");
}
}
TEST_SERVICE(spci_donate_check_upper_bound)
{
exception_setup(NULL, exception_handler_yield_data_abort);
for (;;) {
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint8_t index;
void *recv_buf = SERVICE_RECV_BUFFER();
struct spci_memory_region *memory_region;
struct spci_memory_region_constituent *constituents;
exception_handler_reset();
EXPECT_EQ(ret.func, SPCI_MEM_DONATE_32);
memory_region = (struct spci_memory_region *)recv_buf;
constituents =
spci_memory_region_get_constituents(memory_region);
/* Choose which constituent we want to test. */
index = *(uint8_t *)constituents[0].address;
ptr = (uint8_t *)constituents[index].address;
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
/*
* Check that one cannot access out of bounds after donated
* region. This should trigger the exception handler.
*/
ptr[PAGE_SIZE]++;
}
}
TEST_SERVICE(spci_donate_check_lower_bound)
{
exception_setup(NULL, exception_handler_yield_data_abort);
for (;;) {
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint8_t index;
void *recv_buf = SERVICE_RECV_BUFFER();
struct spci_memory_region *memory_region;
struct spci_memory_region_constituent *constituents;
exception_handler_reset();
EXPECT_EQ(ret.func, SPCI_MEM_DONATE_32);
memory_region = (struct spci_memory_region *)recv_buf;
constituents =
spci_memory_region_get_constituents(memory_region);
/* Choose which constituent we want to test. */
index = *(uint8_t *)constituents[0].address;
ptr = (uint8_t *)constituents[index].address;
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
/*
* Check that one cannot access out of bounds after donated
* region. This should trigger the exception handler.
*/
ptr[-1]++;
}
}
/**
* Attempt to donate memory and then modify.
*/
TEST_SERVICE(spci_donate_secondary_and_fault)
{
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint32_t msg_size;
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
EXPECT_EQ(ret.func, SPCI_MEM_DONATE_32);
exception_setup(NULL, exception_handler_yield_data_abort);
ptr = (uint8_t *)constituents[0].address;
/* Donate memory to next VM. */
msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), SERVICE_VM2, constituents,
memory_region->constituent_count, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
EXPECT_EQ(spci_mem_donate(msg_size, msg_size, 0).func, SPCI_SUCCESS_32);
/* Ensure that we are unable to modify memory any more. */
ptr[0] = 'c';
FAIL("Exception not generated by invalid access.");
}
/**
* Attempt to donate memory twice from VM.
*/
TEST_SERVICE(spci_donate_twice)
{
uint32_t msg_size;
struct spci_value ret = spci_msg_wait();
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent constituent =
spci_memory_region_get_constituents(memory_region)[0];
EXPECT_EQ(ret.func, SPCI_MEM_DONATE_32);
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
/* Yield to allow attempt to re donate from primary. */
spci_yield();
/* Give the memory back and notify the sender. */
msg_size = spci_memory_region_init(
send_buf, SERVICE_VM1, HF_PRIMARY_VM_ID, &constituent, 1, 0, 0,
SPCI_MEMORY_RW_X, SPCI_MEMORY_NORMAL_MEM,
SPCI_MEMORY_CACHE_WRITE_BACK, SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_mem_donate(msg_size, msg_size, 0).func, SPCI_SUCCESS_32);
/* Attempt to donate the memory to another VM. */
msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), SERVICE_VM2, &constituent, 1, 0, 0,
SPCI_MEMORY_RW_X, SPCI_MEMORY_NORMAL_MEM,
SPCI_MEMORY_CACHE_WRITE_BACK, SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_SPCI_ERROR(spci_mem_donate(msg_size, msg_size, 0),
SPCI_INVALID_PARAMETERS);
spci_yield();
}
/**
* Continually receive memory, check if we have access and ensure it is not
* changed by a third party.
*/
TEST_SERVICE(spci_memory_receive)
{
for (;;) {
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
void *recv_buf = SERVICE_RECV_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
EXPECT_EQ(ret.func, SPCI_MEM_DONATE_32);
ptr = (uint8_t *)constituents[0].address;
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
ptr[0] = 'd';
spci_yield();
/* Ensure memory has not changed. */
EXPECT_EQ(ptr[0], 'd');
spci_yield();
}
}
/**
* Receive memory and attempt to donate from primary VM.
*/
TEST_SERVICE(spci_donate_invalid_source)
{
uint32_t msg_size;
struct spci_value ret = spci_msg_wait();
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
EXPECT_EQ(ret.func, SPCI_MEM_DONATE_32);
/* Give the memory back and notify the sender. */
msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), HF_PRIMARY_VM_ID, constituents,
memory_region->constituent_count, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_mem_donate(msg_size, msg_size, 0).func, SPCI_SUCCESS_32);
/* Fail to donate the memory from the primary to VM2. */
msg_size = spci_memory_region_init(
send_buf, HF_PRIMARY_VM_ID, SERVICE_VM2, constituents,
memory_region->constituent_count, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
EXPECT_SPCI_ERROR(spci_mem_donate(msg_size, msg_size, 0),
SPCI_INVALID_PARAMETERS);
spci_yield();
}
TEST_SERVICE(spci_memory_lend_relinquish)
{
exception_setup(NULL, exception_handler_yield_data_abort);
/* Loop, giving memory back to the sender. */
for (;;) {
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint8_t *ptr2;
uint32_t count;
uint32_t count2;
uint32_t msg_size;
size_t i;
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
/*
* The memory may have been sent in one of several different
* ways.
*/
EXPECT_TRUE(ret.func == SPCI_MEM_DONATE_32 ||
ret.func == SPCI_MEM_LEND_32 ||
ret.func == SPCI_MEM_SHARE_32);
ptr = (uint8_t *)constituents[0].address;
count = constituents[0].page_count;
ptr2 = (uint8_t *)constituents[1].address;
count2 = constituents[1].page_count;
/* Check that one has access to the shared region. */
for (i = 0; i < PAGE_SIZE * count; ++i) {
ptr[i]++;
}
for (i = 0; i < PAGE_SIZE * count2; ++i) {
ptr2[i]++;
}
/* Give the memory back and notify the sender. */
msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), memory_region->sender,
constituents, memory_region->constituent_count, 0, 0,
SPCI_MEMORY_RW_X, SPCI_MEMORY_NORMAL_MEM,
SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
/* Relevant information read, mailbox can be cleared. */
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
EXPECT_EQ(hf_spci_mem_relinquish(msg_size, msg_size, 0).func,
SPCI_SUCCESS_32);
/*
* Try and access the memory which will cause a fault unless the
* memory has been shared back again.
*/
ptr[0] = 123;
}
}
/**
* Ensure that we can't relinquish donated memory.
*/
TEST_SERVICE(spci_memory_donate_relinquish)
{
for (;;) {
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint32_t msg_size;
size_t i;
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
EXPECT_EQ(ret.func, SPCI_MEM_DONATE_32);
ptr = (uint8_t *)constituents[0].address;
/* Check that we have access to the shared region. */
for (i = 0; i < PAGE_SIZE; ++i) {
ptr[i]++;
}
/*
* Attempt to relinquish the memory, which should fail because
* it was donated not lent.
*/
msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), HF_PRIMARY_VM_ID,
constituents, memory_region->constituent_count, 0, 0,
SPCI_MEMORY_RW_X, SPCI_MEMORY_NORMAL_MEM,
SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
EXPECT_SPCI_ERROR(hf_spci_mem_relinquish(msg_size, msg_size, 0),
SPCI_INVALID_PARAMETERS);
/* Ensure we still have access to the memory. */
ptr[0] = 123;
spci_yield();
}
}
/**
* Receive memory and attempt to donate from primary VM.
*/
TEST_SERVICE(spci_lend_invalid_source)
{
uint32_t msg_size;
struct spci_value ret = spci_msg_wait();
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
EXPECT_EQ(ret.func, SPCI_MEM_LEND_32);
/* Attempt to relinquish to this same VM. */
msg_size = spci_memory_region_init(
send_buf, HF_PRIMARY_VM_ID, hf_vm_get_id(), constituents,
memory_region->constituent_count, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_SPCI_ERROR(hf_spci_mem_relinquish(msg_size, msg_size, 0),
SPCI_INVALID_PARAMETERS);
/* Give the memory back and notify the sender. */
msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), HF_PRIMARY_VM_ID, constituents,
memory_region->constituent_count, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(hf_spci_mem_relinquish(msg_size, msg_size, 0).func,
SPCI_SUCCESS_32);
/* Ensure we cannot lend from the primary to another secondary. */
msg_size = spci_memory_region_init(
send_buf, HF_PRIMARY_VM_ID, SERVICE_VM2, constituents,
memory_region->constituent_count, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_SPCI_ERROR(spci_mem_lend(msg_size, msg_size, 0),
SPCI_INVALID_PARAMETERS);
/* Ensure we cannot share from the primary to another secondary. */
msg_size = spci_memory_region_init(
send_buf, HF_PRIMARY_VM_ID, SERVICE_VM2, constituents,
memory_region->constituent_count, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
EXPECT_SPCI_ERROR(spci_mem_share(msg_size, msg_size, 0),
SPCI_INVALID_PARAMETERS);
spci_yield();
}
/**
* Attempt to execute an instruction from the lent memory.
*/
TEST_SERVICE(spci_memory_lend_relinquish_X)
{
exception_setup(NULL, exception_handler_yield_instruction_abort);
for (;;) {
struct spci_value ret = spci_msg_wait();
uint64_t *ptr;
uint32_t msg_size;
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
EXPECT_EQ(ret.func, SPCI_MEM_LEND_32);
ptr = (uint64_t *)constituents[0].address;
/*
* Verify that the instruction in memory is the encoded RET
* instruction.
*/
EXPECT_EQ(*ptr, 0xD65F03C0);
/* Try to execute instruction from the shared memory region. */
__asm__ volatile("blr %0" ::"r"(ptr));
/* Release the memory again. */
msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), HF_PRIMARY_VM_ID,
constituents, memory_region->constituent_count, 0, 0,
SPCI_MEMORY_RW_X, SPCI_MEMORY_NORMAL_MEM,
SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
EXPECT_EQ(hf_spci_mem_relinquish(msg_size, msg_size, 0).func,
SPCI_SUCCESS_32);
}
}
/**
* Attempt to read and write to a shared page.
*/
TEST_SERVICE(spci_memory_lend_relinquish_RW)
{
exception_setup(NULL, exception_handler_yield_data_abort);
for (;;) {
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint32_t msg_size;
size_t i;
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
struct spci_memory_region_constituent constituent_copy =
constituents[0];
/*
* The memory may have been sent in one of several different
* ways.
*/
EXPECT_TRUE(ret.func == SPCI_MEM_DONATE_32 ||
ret.func == SPCI_MEM_LEND_32 ||
ret.func == SPCI_MEM_SHARE_32);
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
ptr = (uint8_t *)constituent_copy.address;
/* Check that we have read access. */
for (i = 0; i < PAGE_SIZE; ++i) {
EXPECT_EQ(ptr[i], 'b');
}
/* Return control to primary, to verify shared access. */
spci_yield();
/* Attempt to modify the memory. */
for (i = 0; i < PAGE_SIZE; ++i) {
ptr[i]++;
}
msg_size = spci_memory_region_init(
send_buf, hf_vm_get_id(), HF_PRIMARY_VM_ID,
&constituent_copy, 1, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_EQ(hf_spci_mem_relinquish(msg_size, msg_size, 0).func,
SPCI_SUCCESS_32);
}
}
/**
* Attempt to modify above the upper bound for the lent memory.
*/
TEST_SERVICE(spci_lend_check_upper_bound)
{
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint8_t index;
void *recv_buf = SERVICE_RECV_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
EXPECT_EQ(ret.func, SPCI_MEM_LEND_32);
exception_setup(NULL, exception_handler_yield_data_abort);
/* Choose which constituent we want to test. */
index = *(uint8_t *)constituents[0].address;
ptr = (uint8_t *)constituents[index].address;
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
/* Check that one cannot access after lent region. */
ASSERT_EQ(ptr[PAGE_SIZE], 0);
FAIL("Exception not generated by invalid access.");
}
/**
* Attempt to modify below the lower bound for the lent memory.
*/
TEST_SERVICE(spci_lend_check_lower_bound)
{
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint8_t index;
void *recv_buf = SERVICE_RECV_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
exception_setup(NULL, exception_handler_yield_data_abort);
EXPECT_EQ(ret.func, SPCI_MEM_LEND_32);
/* Choose which constituent we want to test. */
index = *(uint8_t *)constituents[0].address;
ptr = (uint8_t *)constituents[index].address;
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
/* Check that one cannot access after lent region. */
ptr[-1]++;
FAIL("Exception not generated by invalid access.");
}
TEST_SERVICE(spci_memory_lend_twice)
{
struct spci_value ret = spci_msg_wait();
uint8_t *ptr;
uint32_t msg_size;
size_t i;
void *recv_buf = SERVICE_RECV_BUFFER();
void *send_buf = SERVICE_SEND_BUFFER();
struct spci_memory_region *memory_region =
(struct spci_memory_region *)recv_buf;
struct spci_memory_region_constituent *constituents =
spci_memory_region_get_constituents(memory_region);
struct spci_memory_region_constituent constituent_copy =
constituents[0];
/* The memory may have been sent in one of several different ways. */
EXPECT_TRUE(ret.func == SPCI_MEM_DONATE_32 ||
ret.func == SPCI_MEM_LEND_32 ||
ret.func == SPCI_MEM_SHARE_32);
EXPECT_EQ(spci_rx_release().func, SPCI_SUCCESS_32);
ptr = (uint8_t *)constituent_copy.address;
/* Check that we have read access. */
for (i = 0; i < PAGE_SIZE; ++i) {
EXPECT_EQ(ptr[i], 'b');
}
/* Attempt to modify the memory. */
for (i = 0; i < PAGE_SIZE; ++i) {
ptr[i]++;
}
for (i = 1; i < PAGE_SIZE * 2; i++) {
constituent_copy.address = (uint64_t)ptr + i;
/* Fail to lend or share the memory from the primary. */
msg_size = spci_memory_region_init(
send_buf, HF_PRIMARY_VM_ID, SERVICE_VM2,
&constituent_copy, 1, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_SPCI_ERROR(spci_mem_lend(msg_size, msg_size, 0),
SPCI_INVALID_PARAMETERS);
msg_size = spci_memory_region_init(
send_buf, HF_PRIMARY_VM_ID, SERVICE_VM2,
&constituent_copy, 1, 0, 0, SPCI_MEMORY_RW_X,
SPCI_MEMORY_NORMAL_MEM, SPCI_MEMORY_CACHE_WRITE_BACK,
SPCI_MEMORY_OUTER_SHAREABLE);
EXPECT_SPCI_ERROR(spci_mem_share(msg_size, msg_size, 0),
SPCI_INVALID_PARAMETERS);
}
/* Return control to primary. */
spci_yield();
}