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qemu-patch-raspberry4/tests/e1000e-test.c
David Gibson b4ba67d9a7 libqos: Change PCI accessors to take opaque BAR handle 
The usual use model for the libqos PCI functions is to map a specific PCI
BAR using qpci_iomap() then pass the returned token into IO accessor
functions.  This, and the fact that iomap() returns a (void *) which
actually contains a PCI space address, kind of suggests that the return
value from iomap is supposed to be an opaque token.

..except that the callers expect to be able to add offsets to it.  Which
also assumes the compiler will support pointer arithmetic on a (void *),
and treat it as working with byte offsets.

To clarify this situation change iomap() and the IO accessors to take
a definitely opaque BAR handle (enforced with a wrapper struct) along with
an offset within the BAR.  This changes both the functions and all the
callers.

There were a number of places that checked if iomap() returned non-NULL,
and or initialized it to NULL before hand.  Since iomap() already assert()s
if it fails to map the BAR, these tests were mostly pointless and are
removed.

Signed-off-by: David Gibson <david@gibson.dropbear.id.au>
Reviewed-by: Greg Kurz <groug@kaod.org>
2016-10-28 09:38:27 +11:00

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/*
* QTest testcase for e1000e NIC
*
* Copyright (c) 2015 Ravello Systems LTD (http://ravellosystems.com)
* Developed by Daynix Computing LTD (http://www.daynix.com)
*
* Authors:
* Dmitry Fleytman <dmitry@daynix.com>
* Leonid Bloch <leonid@daynix.com>
* Yan Vugenfirer <yan@daynix.com>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see <http://www.gnu.org/licenses/>.
*/
#include "qemu/osdep.h"
#include "libqtest.h"
#include "qemu-common.h"
#include "libqos/pci-pc.h"
#include "qemu/sockets.h"
#include "qemu/iov.h"
#include "qemu/bitops.h"
#include "libqos/malloc.h"
#include "libqos/malloc-pc.h"
#include "libqos/malloc-generic.h"
#define E1000E_IMS (0x00d0)
#define E1000E_STATUS (0x0008)
#define E1000E_STATUS_LU BIT(1)
#define E1000E_STATUS_ASDV1000 BIT(9)
#define E1000E_CTRL (0x0000)
#define E1000E_CTRL_RESET BIT(26)
#define E1000E_RCTL (0x0100)
#define E1000E_RCTL_EN BIT(1)
#define E1000E_RCTL_UPE BIT(3)
#define E1000E_RCTL_MPE BIT(4)
#define E1000E_RFCTL (0x5008)
#define E1000E_RFCTL_EXTEN BIT(15)
#define E1000E_TCTL (0x0400)
#define E1000E_TCTL_EN BIT(1)
#define E1000E_CTRL_EXT (0x0018)
#define E1000E_CTRL_EXT_DRV_LOAD BIT(28)
#define E1000E_CTRL_EXT_TXLSFLOW BIT(22)
#define E1000E_RX0_MSG_ID (0)
#define E1000E_TX0_MSG_ID (1)
#define E1000E_OTHER_MSG_ID (2)
#define E1000E_IVAR (0x00E4)
#define E1000E_IVAR_TEST_CFG ((E1000E_RX0_MSG_ID << 0) | BIT(3) | \
(E1000E_TX0_MSG_ID << 8) | BIT(11) | \
(E1000E_OTHER_MSG_ID << 16) | BIT(19) | \
BIT(31))
#define E1000E_RING_LEN (0x1000)
#define E1000E_TXD_LEN (16)
#define E1000E_RXD_LEN (16)
#define E1000E_TDBAL (0x3800)
#define E1000E_TDBAH (0x3804)
#define E1000E_TDLEN (0x3808)
#define E1000E_TDH (0x3810)
#define E1000E_TDT (0x3818)
#define E1000E_RDBAL (0x2800)
#define E1000E_RDBAH (0x2804)
#define E1000E_RDLEN (0x2808)
#define E1000E_RDH (0x2810)
#define E1000E_RDT (0x2818)
typedef struct e1000e_device {
QPCIDevice *pci_dev;
QPCIBar mac_regs;
uint64_t tx_ring;
uint64_t rx_ring;
} e1000e_device;
static int test_sockets[2];
static QGuestAllocator *test_alloc;
static QPCIBus *test_bus;
static void e1000e_pci_foreach_callback(QPCIDevice *dev, int devfn, void *data)
{
*(QPCIDevice **) data = dev;
}
static QPCIDevice *e1000e_device_find(QPCIBus *bus)
{
static const int e1000e_vendor_id = 0x8086;
static const int e1000e_dev_id = 0x10D3;
QPCIDevice *e1000e_dev = NULL;
qpci_device_foreach(bus, e1000e_vendor_id, e1000e_dev_id,
e1000e_pci_foreach_callback, &e1000e_dev);
g_assert_nonnull(e1000e_dev);
return e1000e_dev;
}
static void e1000e_macreg_write(e1000e_device *d, uint32_t reg, uint32_t val)
{
qpci_io_writel(d->pci_dev, d->mac_regs, reg, val);
}
static uint32_t e1000e_macreg_read(e1000e_device *d, uint32_t reg)
{
return qpci_io_readl(d->pci_dev, d->mac_regs, reg);
}
static void e1000e_device_init(QPCIBus *bus, e1000e_device *d)
{
uint32_t val;
d->pci_dev = e1000e_device_find(bus);
/* Enable the device */
qpci_device_enable(d->pci_dev);
/* Map BAR0 (mac registers) */
d->mac_regs = qpci_iomap(d->pci_dev, 0, NULL);
/* Reset the device */
val = e1000e_macreg_read(d, E1000E_CTRL);
e1000e_macreg_write(d, E1000E_CTRL, val | E1000E_CTRL_RESET);
/* Enable and configure MSI-X */
qpci_msix_enable(d->pci_dev);
e1000e_macreg_write(d, E1000E_IVAR, E1000E_IVAR_TEST_CFG);
/* Check the device status - link and speed */
val = e1000e_macreg_read(d, E1000E_STATUS);
g_assert_cmphex(val & (E1000E_STATUS_LU | E1000E_STATUS_ASDV1000),
==, E1000E_STATUS_LU | E1000E_STATUS_ASDV1000);
/* Initialize TX/RX logic */
e1000e_macreg_write(d, E1000E_RCTL, 0);
e1000e_macreg_write(d, E1000E_TCTL, 0);
/* Notify the device that the driver is ready */
val = e1000e_macreg_read(d, E1000E_CTRL_EXT);
e1000e_macreg_write(d, E1000E_CTRL_EXT,
val | E1000E_CTRL_EXT_DRV_LOAD | E1000E_CTRL_EXT_TXLSFLOW);
/* Allocate and setup TX ring */
d->tx_ring = guest_alloc(test_alloc, E1000E_RING_LEN);
g_assert(d->tx_ring != 0);
e1000e_macreg_write(d, E1000E_TDBAL, (uint32_t) d->tx_ring);
e1000e_macreg_write(d, E1000E_TDBAH, (uint32_t) (d->tx_ring >> 32));
e1000e_macreg_write(d, E1000E_TDLEN, E1000E_RING_LEN);
e1000e_macreg_write(d, E1000E_TDT, 0);
e1000e_macreg_write(d, E1000E_TDH, 0);
/* Enable transmit */
e1000e_macreg_write(d, E1000E_TCTL, E1000E_TCTL_EN);
/* Allocate and setup RX ring */
d->rx_ring = guest_alloc(test_alloc, E1000E_RING_LEN);
g_assert(d->rx_ring != 0);
e1000e_macreg_write(d, E1000E_RDBAL, (uint32_t)d->rx_ring);
e1000e_macreg_write(d, E1000E_RDBAH, (uint32_t)(d->rx_ring >> 32));
e1000e_macreg_write(d, E1000E_RDLEN, E1000E_RING_LEN);
e1000e_macreg_write(d, E1000E_RDT, 0);
e1000e_macreg_write(d, E1000E_RDH, 0);
/* Enable receive */
e1000e_macreg_write(d, E1000E_RFCTL, E1000E_RFCTL_EXTEN);
e1000e_macreg_write(d, E1000E_RCTL, E1000E_RCTL_EN |
E1000E_RCTL_UPE |
E1000E_RCTL_MPE);
/* Enable all interrupts */
e1000e_macreg_write(d, E1000E_IMS, 0xFFFFFFFF);
}
static void e1000e_tx_ring_push(e1000e_device *d, void *descr)
{
uint32_t tail = e1000e_macreg_read(d, E1000E_TDT);
uint32_t len = e1000e_macreg_read(d, E1000E_TDLEN) / E1000E_TXD_LEN;
memwrite(d->tx_ring + tail * E1000E_TXD_LEN, descr, E1000E_TXD_LEN);
e1000e_macreg_write(d, E1000E_TDT, (tail + 1) % len);
/* Read WB data for the packet transmitted */
memread(d->tx_ring + tail * E1000E_TXD_LEN, descr, E1000E_TXD_LEN);
}
static void e1000e_rx_ring_push(e1000e_device *d, void *descr)
{
uint32_t tail = e1000e_macreg_read(d, E1000E_RDT);
uint32_t len = e1000e_macreg_read(d, E1000E_RDLEN) / E1000E_RXD_LEN;
memwrite(d->rx_ring + tail * E1000E_RXD_LEN, descr, E1000E_RXD_LEN);
e1000e_macreg_write(d, E1000E_RDT, (tail + 1) % len);
/* Read WB data for the packet received */
memread(d->rx_ring + tail * E1000E_RXD_LEN, descr, E1000E_RXD_LEN);
}
static void e1000e_wait_isr(e1000e_device *d, uint16_t msg_id)
{
guint64 end_time = g_get_monotonic_time() + 5 * G_TIME_SPAN_SECOND;
do {
if (qpci_msix_pending(d->pci_dev, msg_id)) {
return;
}
clock_step(10000);
} while (g_get_monotonic_time() < end_time);
g_error("Timeout expired");
}
static void e1000e_send_verify(e1000e_device *d)
{
struct {
uint64_t buffer_addr;
union {
uint32_t data;
struct {
uint16_t length;
uint8_t cso;
uint8_t cmd;
} flags;
} lower;
union {
uint32_t data;
struct {
uint8_t status;
uint8_t css;
uint16_t special;
} fields;
} upper;
} descr;
static const uint32_t dtyp_data = BIT(20);
static const uint32_t dtyp_ext = BIT(29);
static const uint32_t dcmd_rs = BIT(27);
static const uint32_t dcmd_eop = BIT(24);
static const uint32_t dsta_dd = BIT(0);
static const int data_len = 64;
char buffer[64];
int ret;
uint32_t recv_len;
/* Prepare test data buffer */
uint64_t data = guest_alloc(test_alloc, data_len);
memwrite(data, "TEST", 5);
/* Prepare TX descriptor */
memset(&descr, 0, sizeof(descr));
descr.buffer_addr = cpu_to_le64(data);
descr.lower.data = cpu_to_le32(dcmd_rs |
dcmd_eop |
dtyp_ext |
dtyp_data |
data_len);
/* Put descriptor to the ring */
e1000e_tx_ring_push(d, &descr);
/* Wait for TX WB interrupt */
e1000e_wait_isr(d, E1000E_TX0_MSG_ID);
/* Check DD bit */
g_assert_cmphex(le32_to_cpu(descr.upper.data) & dsta_dd, ==, dsta_dd);
/* Check data sent to the backend */
ret = qemu_recv(test_sockets[0], &recv_len, sizeof(recv_len), 0);
g_assert_cmpint(ret, == , sizeof(recv_len));
qemu_recv(test_sockets[0], buffer, 64, 0);
g_assert_cmpstr(buffer, == , "TEST");
/* Free test data buffer */
guest_free(test_alloc, data);
}
static void e1000e_receive_verify(e1000e_device *d)
{
union {
struct {
uint64_t buffer_addr;
uint64_t reserved;
} read;
struct {
struct {
uint32_t mrq;
union {
uint32_t rss;
struct {
uint16_t ip_id;
uint16_t csum;
} csum_ip;
} hi_dword;
} lower;
struct {
uint32_t status_error;
uint16_t length;
uint16_t vlan;
} upper;
} wb;
} descr;
static const uint32_t esta_dd = BIT(0);
char test[] = "TEST";
int len = htonl(sizeof(test));
struct iovec iov[] = {
{
.iov_base = &len,
.iov_len = sizeof(len),
},{
.iov_base = test,
.iov_len = sizeof(test),
},
};
static const int data_len = 64;
char buffer[64];
int ret;
/* Send a dummy packet to device's socket*/
ret = iov_send(test_sockets[0], iov, 2, 0, sizeof(len) + sizeof(test));
g_assert_cmpint(ret, == , sizeof(test) + sizeof(len));
/* Prepare test data buffer */
uint64_t data = guest_alloc(test_alloc, data_len);
/* Prepare RX descriptor */
memset(&descr, 0, sizeof(descr));
descr.read.buffer_addr = cpu_to_le64(data);
/* Put descriptor to the ring */
e1000e_rx_ring_push(d, &descr);
/* Wait for TX WB interrupt */
e1000e_wait_isr(d, E1000E_RX0_MSG_ID);
/* Check DD bit */
g_assert_cmphex(le32_to_cpu(descr.wb.upper.status_error) &
esta_dd, ==, esta_dd);
/* Check data sent to the backend */
memread(data, buffer, sizeof(buffer));
g_assert_cmpstr(buffer, == , "TEST");
/* Free test data buffer */
guest_free(test_alloc, data);
}
static void e1000e_device_clear(QPCIBus *bus, e1000e_device *d)
{
qpci_iounmap(d->pci_dev, d->mac_regs);
qpci_msix_disable(d->pci_dev);
}
static void data_test_init(e1000e_device *d)
{
char *cmdline;
int ret = socketpair(PF_UNIX, SOCK_STREAM, 0, test_sockets);
g_assert_cmpint(ret, != , -1);
cmdline = g_strdup_printf("-netdev socket,fd=%d,id=hs0 "
"-device e1000e,netdev=hs0", test_sockets[1]);
g_assert_nonnull(cmdline);
qtest_start(cmdline);
g_free(cmdline);
test_bus = qpci_init_pc(NULL);
g_assert_nonnull(test_bus);
test_alloc = pc_alloc_init();
g_assert_nonnull(test_alloc);
e1000e_device_init(test_bus, d);
}
static void data_test_clear(e1000e_device *d)
{
e1000e_device_clear(test_bus, d);
close(test_sockets[0]);
pc_alloc_uninit(test_alloc);
qpci_free_pc(test_bus);
qtest_end();
}
static void test_e1000e_init(gconstpointer data)
{
e1000e_device d;
data_test_init(&d);
data_test_clear(&d);
}
static void test_e1000e_tx(gconstpointer data)
{
e1000e_device d;
data_test_init(&d);
e1000e_send_verify(&d);
data_test_clear(&d);
}
static void test_e1000e_rx(gconstpointer data)
{
e1000e_device d;
data_test_init(&d);
e1000e_receive_verify(&d);
data_test_clear(&d);
}
static void test_e1000e_multiple_transfers(gconstpointer data)
{
static const long iterations = 4 * 1024;
long i;
e1000e_device d;
data_test_init(&d);
for (i = 0; i < iterations; i++) {
e1000e_send_verify(&d);
e1000e_receive_verify(&d);
}
data_test_clear(&d);
}
static void test_e1000e_hotplug(gconstpointer data)
{
static const uint8_t slot = 0x06;
qtest_start("-device e1000e");
qpci_plug_device_test("e1000e", "e1000e_net", slot, NULL);
qpci_unplug_acpi_device_test("e1000e_net", slot);
qtest_end();
}
int main(int argc, char **argv)
{
g_test_init(&argc, &argv, NULL);
qtest_add_data_func("e1000e/init", NULL, test_e1000e_init);
qtest_add_data_func("e1000e/tx", NULL, test_e1000e_tx);
qtest_add_data_func("e1000e/rx", NULL, test_e1000e_rx);
qtest_add_data_func("e1000e/multiple_transfers", NULL,
test_e1000e_multiple_transfers);
qtest_add_data_func("e1000e/hotplug", NULL, test_e1000e_hotplug);
return g_test_run();
}
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