| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Sergey Matyukevich | 3723 | 97.97% | 5 | 62.50% |
| Andy Chiu | 63 | 1.66% | 1 | 12.50% |
| Charlie Jenkins | 12 | 0.32% | 1 | 12.50% |
| Paul Walmsley | 2 | 0.05% | 1 | 12.50% |
| Total | 3800 | 8 |
// SPDX-License-Identifier: GPL-2.0-only #include <sys/ptrace.h> #include <sys/types.h> #include <sys/wait.h> #include <sys/uio.h> #include <unistd.h> #include <errno.h> #include <linux/ptrace.h> #include <linux/elf.h> #include "kselftest_harness.h" #include "v_helpers.h" #define SR_FS_DIRTY 0x00006000UL #define CSR_VXRM_SHIFT 1 volatile unsigned long chld_lock; TEST(ptrace_v_not_enabled) { pid_t pid; if (!(is_vector_supported() || is_xtheadvector_supported())) SKIP(return, "Vector not supported"); chld_lock = 1; pid = fork(); ASSERT_LE(0, pid) TH_LOG("fork: %m"); if (pid == 0) { while (chld_lock == 1) asm volatile("" : : "g"(chld_lock) : "memory"); asm volatile ("ebreak" : : : ); } else { struct __riscv_v_regset_state *regset_data; unsigned long vlenb = get_vr_len(); size_t regset_size; struct iovec iov; int status; int ret; /* attach */ ASSERT_EQ(0, ptrace(PTRACE_ATTACH, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* unlock */ ASSERT_EQ(0, ptrace(PTRACE_POKEDATA, pid, &chld_lock, 0)); /* resume and wait for ebreak */ ASSERT_EQ(0, ptrace(PTRACE_CONT, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* try to read vector registers from the tracee */ regset_size = sizeof(*regset_data) + vlenb * 32; regset_data = calloc(1, regset_size); iov.iov_base = regset_data; iov.iov_len = regset_size; /* V extension is available, but not yet enabled for the tracee */ errno = 0; ret = ptrace(PTRACE_GETREGSET, pid, NT_RISCV_VECTOR, &iov); ASSERT_EQ(ENODATA, errno); ASSERT_EQ(-1, ret); /* cleanup */ ASSERT_EQ(0, kill(pid, SIGKILL)); } } TEST(ptrace_v_early_debug) { static volatile unsigned long vstart; static volatile unsigned long vtype; static volatile unsigned long vlenb; static volatile unsigned long vcsr; static volatile unsigned long vl; bool xtheadvector; pid_t pid; if (!(is_vector_supported() || is_xtheadvector_supported())) SKIP(return, "Vector not supported"); xtheadvector = is_xtheadvector_supported(); chld_lock = 1; pid = fork(); ASSERT_LE(0, pid) TH_LOG("fork: %m"); if (pid == 0) { unsigned long vxsat, vxrm; vlenb = get_vr_len(); while (chld_lock == 1) asm volatile ("" : : "g"(chld_lock) : "memory"); asm volatile ( "csrr %[vstart], vstart\n" "csrr %[vtype], vtype\n" "csrr %[vl], vl\n" : [vtype] "=r"(vtype), [vstart] "=r"(vstart), [vl] "=r"(vl) : : "memory"); /* no 'is_xtheadvector_supported()' here to avoid clobbering v-state by syscall */ if (xtheadvector) { asm volatile ( "csrs sstatus, %[bit]\n" "csrr %[vxsat], vxsat\n" "csrr %[vxrm], vxrm\n" : [vxsat] "=r"(vxsat), [vxrm] "=r"(vxrm) : [bit] "r" (SR_FS_DIRTY) : "memory"); vcsr = vxsat | vxrm << CSR_VXRM_SHIFT; } else { asm volatile ( "csrr %[vcsr], vcsr\n" : [vcsr] "=r"(vcsr) : : "memory"); } asm volatile ( ".option push\n" ".option norvc\n" "ebreak\n" ".option pop\n"); } else { struct __riscv_v_regset_state *regset_data; unsigned long vstart_csr; unsigned long vlenb_csr; unsigned long vtype_csr; unsigned long vcsr_csr; unsigned long vl_csr; size_t regset_size; struct iovec iov; int status; /* attach */ ASSERT_EQ(0, ptrace(PTRACE_ATTACH, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* unlock */ ASSERT_EQ(0, ptrace(PTRACE_POKEDATA, pid, &chld_lock, 0)); /* resume and wait for ebreak */ ASSERT_EQ(0, ptrace(PTRACE_CONT, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* read tracee vector csr regs using ptrace PEEKDATA */ errno = 0; vstart_csr = ptrace(PTRACE_PEEKDATA, pid, &vstart, NULL); ASSERT_FALSE((errno != 0) && (vstart_csr == -1)); errno = 0; vl_csr = ptrace(PTRACE_PEEKDATA, pid, &vl, NULL); ASSERT_FALSE((errno != 0) && (vl_csr == -1)); errno = 0; vtype_csr = ptrace(PTRACE_PEEKDATA, pid, &vtype, NULL); ASSERT_FALSE((errno != 0) && (vtype_csr == -1)); errno = 0; vcsr_csr = ptrace(PTRACE_PEEKDATA, pid, &vcsr, NULL); ASSERT_FALSE((errno != 0) && (vcsr_csr == -1)); errno = 0; vlenb_csr = ptrace(PTRACE_PEEKDATA, pid, &vlenb, NULL); ASSERT_FALSE((errno != 0) && (vlenb_csr == -1)); /* read tracee csr regs using ptrace GETREGSET */ regset_size = sizeof(*regset_data) + vlenb_csr * 32; regset_data = calloc(1, regset_size); iov.iov_base = regset_data; iov.iov_len = regset_size; ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_RISCV_VECTOR, &iov)); /* compare */ EXPECT_EQ(vstart_csr, regset_data->vstart); EXPECT_EQ(vtype_csr, regset_data->vtype); EXPECT_EQ(vlenb_csr, regset_data->vlenb); EXPECT_EQ(vcsr_csr, regset_data->vcsr); EXPECT_EQ(vl_csr, regset_data->vl); /* cleanup */ ASSERT_EQ(0, kill(pid, SIGKILL)); } } TEST(ptrace_v_syscall_clobbering) { pid_t pid; if (!is_vector_supported() && !is_xtheadvector_supported()) SKIP(return, "Vector not supported"); chld_lock = 1; pid = fork(); ASSERT_LE(0, pid) TH_LOG("fork: %m"); if (pid == 0) { unsigned long vl; while (chld_lock == 1) asm volatile("" : : "g"(chld_lock) : "memory"); if (is_xtheadvector_supported()) { asm volatile ( // 0 | zimm[10:0] | rs1 | 1 1 1 | rd |1010111| vsetvli // vsetvli t4, x0, e16, m2, d1 ".4byte 0b00000000010100000111111011010111\n" "mv %[new_vl], t4\n" : [new_vl] "=r" (vl) : : "t4"); } else { asm volatile ( ".option push\n" ".option arch, +zve32x\n" "vsetvli %[new_vl], x0, e16, m2, tu, mu\n" ".option pop\n" : [new_vl] "=r"(vl) : : ); } while (1) { asm volatile ( ".option push\n" ".option norvc\n" "ebreak\n" ".option pop\n"); sleep(0); } } else { struct __riscv_v_regset_state *regset_data; unsigned long vlenb = get_vr_len(); struct user_regs_struct regs; size_t regset_size; struct iovec iov; int status; /* attach */ ASSERT_EQ(0, ptrace(PTRACE_ATTACH, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* unlock */ ASSERT_EQ(0, ptrace(PTRACE_POKEDATA, pid, &chld_lock, 0)); /* resume and wait for the 1st ebreak */ ASSERT_EQ(0, ptrace(PTRACE_CONT, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* read tracee vector csr regs using ptrace GETREGSET */ regset_size = sizeof(*regset_data) + vlenb * 32; regset_data = calloc(1, regset_size); iov.iov_base = regset_data; iov.iov_len = regset_size; ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_RISCV_VECTOR, &iov)); /* verify initial vsetvli settings */ if (is_xtheadvector_supported()) { EXPECT_EQ(5UL, regset_data->vtype); } else { EXPECT_EQ(9UL, regset_data->vtype); } EXPECT_EQ(regset_data->vlenb, regset_data->vl); EXPECT_EQ(vlenb, regset_data->vlenb); EXPECT_EQ(0UL, regset_data->vstart); EXPECT_EQ(0UL, regset_data->vcsr); /* skip 1st ebreak, then resume and wait for the 2nd ebreak */ iov.iov_base = ®s; iov.iov_len = sizeof(regs); ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_PRSTATUS, &iov)); regs.pc += 4; ASSERT_EQ(0, ptrace(PTRACE_SETREGSET, pid, NT_PRSTATUS, &iov)); ASSERT_EQ(0, ptrace(PTRACE_CONT, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* read tracee vtype using ptrace GETREGSET */ iov.iov_base = regset_data; iov.iov_len = regset_size; ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_RISCV_VECTOR, &iov)); /* verify that V state is illegal after syscall */ EXPECT_EQ((1UL << (__riscv_xlen - 1)), regset_data->vtype); EXPECT_EQ(vlenb, regset_data->vlenb); EXPECT_EQ(0UL, regset_data->vstart); EXPECT_EQ(0UL, regset_data->vcsr); EXPECT_EQ(0UL, regset_data->vl); /* cleanup */ ASSERT_EQ(0, kill(pid, SIGKILL)); } } FIXTURE(v_csr_invalid) { }; FIXTURE_SETUP(v_csr_invalid) { } FIXTURE_TEARDOWN(v_csr_invalid) { } #define VECTOR_1_0 _BITUL(0) #define XTHEAD_VECTOR_0_7 _BITUL(1) #define vector_test(x) ((x) & VECTOR_1_0) #define xthead_test(x) ((x) & XTHEAD_VECTOR_0_7) /* modifications of the initial vsetvli settings */ FIXTURE_VARIANT(v_csr_invalid) { unsigned long vstart; unsigned long vl; unsigned long vtype; unsigned long vcsr; unsigned long vlenb_mul; unsigned long vlenb_min; unsigned long vlenb_max; unsigned long spec; }; /* unexpected vlenb value */ FIXTURE_VARIANT_ADD(v_csr_invalid, new_vlenb) { .vstart = 0x0, .vl = 0x0, .vtype = 0x3, .vcsr = 0x0, .vlenb_mul = 0x2, .vlenb_min = 0x0, .vlenb_max = 0x0, .spec = VECTOR_1_0 | XTHEAD_VECTOR_0_7, }; /* invalid reserved bits in vcsr */ FIXTURE_VARIANT_ADD(v_csr_invalid, vcsr_invalid_reserved_bits) { .vstart = 0x0, .vl = 0x0, .vtype = 0x3, .vcsr = 0x1UL << 8, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x0, .spec = VECTOR_1_0 | XTHEAD_VECTOR_0_7, }; /* invalid reserved bits in vtype */ FIXTURE_VARIANT_ADD(v_csr_invalid, vtype_invalid_reserved_bits) { .vstart = 0x0, .vl = 0x0, .vtype = (0x1UL << 8) | 0x3, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x0, .spec = VECTOR_1_0 | XTHEAD_VECTOR_0_7, }; /* set vill bit */ FIXTURE_VARIANT_ADD(v_csr_invalid, invalid_vill_bit) { .vstart = 0x0, .vl = 0x0, .vtype = (0x1UL << (__riscv_xlen - 1)) | 0x3, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x0, .spec = VECTOR_1_0 | XTHEAD_VECTOR_0_7, }; /* reserved vsew value: vsew > 3 */ FIXTURE_VARIANT_ADD(v_csr_invalid, reserved_vsew) { .vstart = 0x0, .vl = 0x0, .vtype = 0x4UL << 3, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x0, .spec = VECTOR_1_0, }; /* XTheadVector: unsupported non-zero VEDIV value */ FIXTURE_VARIANT_ADD(v_csr_invalid, reserved_vediv) { .vstart = 0x0, .vl = 0x0, .vtype = 0x3UL << 5, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x0, .spec = XTHEAD_VECTOR_0_7, }; /* reserved vlmul value: vlmul == 4 */ FIXTURE_VARIANT_ADD(v_csr_invalid, reserved_vlmul) { .vstart = 0x0, .vl = 0x0, .vtype = 0x4, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x0, .spec = VECTOR_1_0, }; /* invalid fractional LMUL for VLEN <= 256: LMUL= 1/8, SEW = 64 */ FIXTURE_VARIANT_ADD(v_csr_invalid, frac_lmul1) { .vstart = 0x0, .vl = 0x0, .vtype = 0x1d, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x20, .spec = VECTOR_1_0, }; /* invalid integral LMUL for VLEN <= 16: LMUL= 2, SEW = 64 */ FIXTURE_VARIANT_ADD(v_csr_invalid, int_lmul1) { .vstart = 0x0, .vl = 0x0, .vtype = 0x19, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x2, .spec = VECTOR_1_0, }; /* XTheadVector: invalid integral LMUL for VLEN <= 16: LMUL= 2, SEW = 64 */ FIXTURE_VARIANT_ADD(v_csr_invalid, int_lmul2) { .vstart = 0x0, .vl = 0x0, .vtype = 0xd, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x2, .spec = XTHEAD_VECTOR_0_7, }; /* invalid VL for VLEN <= 128: LMUL= 2, SEW = 64, VL = 8 */ FIXTURE_VARIANT_ADD(v_csr_invalid, vl1) { .vstart = 0x0, .vl = 0x8, .vtype = 0x19, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x10, .spec = VECTOR_1_0, }; /* XTheadVector: invalid VL for VLEN <= 128: LMUL= 2, SEW = 64, VL = 8 */ FIXTURE_VARIANT_ADD(v_csr_invalid, vl2) { .vstart = 0x0, .vl = 0x8, .vtype = 0xd, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x0, .vlenb_max = 0x10, .spec = XTHEAD_VECTOR_0_7, }; TEST_F(v_csr_invalid, ptrace_v_invalid_values) { unsigned long vlenb; pid_t pid; if (!is_vector_supported() && !is_xtheadvector_supported()) SKIP(return, "Vectors not supported"); if (is_vector_supported() && !vector_test(variant->spec)) SKIP(return, "Test not supported for Vector"); if (is_xtheadvector_supported() && !xthead_test(variant->spec)) SKIP(return, "Test not supported for XTheadVector"); vlenb = get_vr_len(); if (variant->vlenb_min) { if (vlenb < variant->vlenb_min) SKIP(return, "This test does not support VLEN < %lu\n", variant->vlenb_min * 8); } if (variant->vlenb_max) { if (vlenb > variant->vlenb_max) SKIP(return, "This test does not support VLEN > %lu\n", variant->vlenb_max * 8); } chld_lock = 1; pid = fork(); ASSERT_LE(0, pid) TH_LOG("fork: %m"); if (pid == 0) { unsigned long vl; while (chld_lock == 1) asm volatile("" : : "g"(chld_lock) : "memory"); if (is_xtheadvector_supported()) { asm volatile ( // 0 | zimm[10:0] | rs1 | 1 1 1 | rd |1010111| vsetvli // vsetvli t4, x0, e16, m2, d1 ".4byte 0b00000000010100000111111011010111\n" "mv %[new_vl], t4\n" : [new_vl] "=r" (vl) : : "t4"); } else { asm volatile ( ".option push\n" ".option arch, +zve32x\n" "vsetvli %[new_vl], x0, e16, m2, tu, mu\n" ".option pop\n" : [new_vl] "=r"(vl) : : ); } while (1) { asm volatile ( ".option push\n" ".option norvc\n" "ebreak\n" "nop\n" ".option pop\n"); } } else { struct __riscv_v_regset_state *regset_data; size_t regset_size; struct iovec iov; int status; int ret; /* attach */ ASSERT_EQ(0, ptrace(PTRACE_ATTACH, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* unlock */ ASSERT_EQ(0, ptrace(PTRACE_POKEDATA, pid, &chld_lock, 0)); /* resume and wait for the 1st ebreak */ ASSERT_EQ(0, ptrace(PTRACE_CONT, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* read tracee vector csr regs using ptrace GETREGSET */ regset_size = sizeof(*regset_data) + vlenb * 32; regset_data = calloc(1, regset_size); iov.iov_base = regset_data; iov.iov_len = regset_size; ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_RISCV_VECTOR, &iov)); /* verify initial vsetvli settings */ if (is_xtheadvector_supported()) { EXPECT_EQ(5UL, regset_data->vtype); } else { EXPECT_EQ(9UL, regset_data->vtype); } EXPECT_EQ(regset_data->vlenb, regset_data->vl); EXPECT_EQ(vlenb, regset_data->vlenb); EXPECT_EQ(0UL, regset_data->vstart); EXPECT_EQ(0UL, regset_data->vcsr); /* apply invalid settings from fixture variants */ regset_data->vlenb *= variant->vlenb_mul; regset_data->vstart = variant->vstart; regset_data->vtype = variant->vtype; regset_data->vcsr = variant->vcsr; regset_data->vl = variant->vl; iov.iov_base = regset_data; iov.iov_len = regset_size; errno = 0; ret = ptrace(PTRACE_SETREGSET, pid, NT_RISCV_VECTOR, &iov); ASSERT_EQ(errno, EINVAL); ASSERT_EQ(ret, -1); /* cleanup */ ASSERT_EQ(0, kill(pid, SIGKILL)); } } FIXTURE(v_csr_valid) { }; FIXTURE_SETUP(v_csr_valid) { } FIXTURE_TEARDOWN(v_csr_valid) { } /* modifications of the initial vsetvli settings */ FIXTURE_VARIANT(v_csr_valid) { unsigned long vstart; unsigned long vl; unsigned long vtype; unsigned long vcsr; unsigned long vlenb_mul; unsigned long vlenb_min; unsigned long vlenb_max; unsigned long spec; }; /* valid for VLEN >= 128: LMUL= 1/4, SEW = 32 */ FIXTURE_VARIANT_ADD(v_csr_valid, frac_lmul1) { .vstart = 0x0, .vl = 0x0, .vtype = 0x16, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x10, .vlenb_max = 0x0, .spec = VECTOR_1_0, }; /* valid for VLEN >= 16: LMUL= 2, SEW = 32 */ FIXTURE_VARIANT_ADD(v_csr_valid, int_lmul1) { .vstart = 0x0, .vl = 0x0, .vtype = 0x11, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x2, .vlenb_max = 0x0, .spec = VECTOR_1_0, }; /* valid for XTheadVector VLEN >= 16: LMUL= 2, SEW = 32 */ FIXTURE_VARIANT_ADD(v_csr_valid, int_lmul2) { .vstart = 0x0, .vl = 0x0, .vtype = 0x9, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x2, .vlenb_max = 0x0, .spec = XTHEAD_VECTOR_0_7, }; /* valid for VLEN >= 32: LMUL= 2, SEW = 32, VL = 2 */ FIXTURE_VARIANT_ADD(v_csr_valid, int_lmul3) { .vstart = 0x0, .vl = 0x2, .vtype = 0x11, .vcsr = 0x0, .vlenb_mul = 0x1, .vlenb_min = 0x4, .vlenb_max = 0x0, .spec = VECTOR_1_0, }; TEST_F(v_csr_valid, ptrace_v_valid_values) { unsigned long vlenb; pid_t pid; if (!is_vector_supported() && !is_xtheadvector_supported()) SKIP(return, "Vectors not supported"); if (is_vector_supported() && !vector_test(variant->spec)) SKIP(return, "Test not supported for Vector"); if (is_xtheadvector_supported() && !xthead_test(variant->spec)) SKIP(return, "Test not supported for XTheadVector"); vlenb = get_vr_len(); if (variant->vlenb_min) { if (vlenb < variant->vlenb_min) SKIP(return, "This test does not support VLEN < %lu\n", variant->vlenb_min * 8); } if (variant->vlenb_max) { if (vlenb > variant->vlenb_max) SKIP(return, "This test does not support VLEN > %lu\n", variant->vlenb_max * 8); } chld_lock = 1; pid = fork(); ASSERT_LE(0, pid) TH_LOG("fork: %m"); if (pid == 0) { unsigned long vl; while (chld_lock == 1) asm volatile("" : : "g"(chld_lock) : "memory"); if (is_xtheadvector_supported()) { asm volatile ( // 0 | zimm[10:0] | rs1 | 1 1 1 | rd |1010111| vsetvli // vsetvli t4, x0, e16, m2, d1 ".4byte 0b00000000010100000111111011010111\n" "mv %[new_vl], t4\n" : [new_vl] "=r" (vl) : : "t4"); } else { asm volatile ( ".option push\n" ".option arch, +zve32x\n" "vsetvli %[new_vl], x0, e16, m2, tu, mu\n" ".option pop\n" : [new_vl] "=r"(vl) : : ); } asm volatile ( ".option push\n" ".option norvc\n" ".option arch, +zve32x\n" "ebreak\n" /* breakpoint 1: apply new V state using ptrace */ "nop\n" "ebreak\n" /* breakpoint 2: V state clean - context will not be saved */ "vmv.v.i v0, -1\n" "ebreak\n" /* breakpoint 3: V state dirty - context will be saved */ ".option pop\n"); } else { struct __riscv_v_regset_state *regset_data; struct user_regs_struct regs; size_t regset_size; struct iovec iov; int status; /* attach */ ASSERT_EQ(0, ptrace(PTRACE_ATTACH, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* unlock */ ASSERT_EQ(0, ptrace(PTRACE_POKEDATA, pid, &chld_lock, 0)); /* resume and wait for the 1st ebreak */ ASSERT_EQ(0, ptrace(PTRACE_CONT, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* read tracee vector csr regs using ptrace GETREGSET */ regset_size = sizeof(*regset_data) + vlenb * 32; regset_data = calloc(1, regset_size); iov.iov_base = regset_data; iov.iov_len = regset_size; ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_RISCV_VECTOR, &iov)); /* verify initial vsetvli settings */ if (is_xtheadvector_supported()) { EXPECT_EQ(5UL, regset_data->vtype); } else { EXPECT_EQ(9UL, regset_data->vtype); } EXPECT_EQ(regset_data->vlenb, regset_data->vl); EXPECT_EQ(vlenb, regset_data->vlenb); EXPECT_EQ(0UL, regset_data->vstart); EXPECT_EQ(0UL, regset_data->vcsr); /* apply valid settings from fixture variants */ regset_data->vlenb *= variant->vlenb_mul; regset_data->vstart = variant->vstart; regset_data->vtype = variant->vtype; regset_data->vcsr = variant->vcsr; regset_data->vl = variant->vl; iov.iov_base = regset_data; iov.iov_len = regset_size; ASSERT_EQ(0, ptrace(PTRACE_SETREGSET, pid, NT_RISCV_VECTOR, &iov)); /* skip 1st ebreak, then resume and wait for the 2nd ebreak */ iov.iov_base = ®s; iov.iov_len = sizeof(regs); ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_PRSTATUS, &iov)); regs.pc += 4; ASSERT_EQ(0, ptrace(PTRACE_SETREGSET, pid, NT_PRSTATUS, &iov)); ASSERT_EQ(0, ptrace(PTRACE_CONT, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* read tracee vector csr regs using ptrace GETREGSET */ iov.iov_base = regset_data; iov.iov_len = regset_size; ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_RISCV_VECTOR, &iov)); /* verify vector csr regs from tracee context */ EXPECT_EQ(regset_data->vstart, variant->vstart); EXPECT_EQ(regset_data->vtype, variant->vtype); EXPECT_EQ(regset_data->vcsr, variant->vcsr); EXPECT_EQ(regset_data->vl, variant->vl); EXPECT_EQ(regset_data->vlenb, vlenb); /* skip 2nd ebreak, then resume and wait for the 3rd ebreak */ iov.iov_base = ®s; iov.iov_len = sizeof(regs); ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_PRSTATUS, &iov)); regs.pc += 4; ASSERT_EQ(0, ptrace(PTRACE_SETREGSET, pid, NT_PRSTATUS, &iov)); ASSERT_EQ(0, ptrace(PTRACE_CONT, pid, NULL, NULL)); ASSERT_EQ(pid, waitpid(pid, &status, 0)); ASSERT_TRUE(WIFSTOPPED(status)); /* read tracee vector csr regs using ptrace GETREGSET */ iov.iov_base = regset_data; iov.iov_len = regset_size; ASSERT_EQ(0, ptrace(PTRACE_GETREGSET, pid, NT_RISCV_VECTOR, &iov)); /* verify vector csr regs from tracee context */ EXPECT_EQ(regset_data->vstart, variant->vstart); EXPECT_EQ(regset_data->vtype, variant->vtype); EXPECT_EQ(regset_data->vcsr, variant->vcsr); EXPECT_EQ(regset_data->vl, variant->vl); EXPECT_EQ(regset_data->vlenb, vlenb); /* cleanup */ ASSERT_EQ(0, kill(pid, SIGKILL)); } } TEST_HARNESS_MAIN
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