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llama.cpp/tests/test-batch-alloc.cpp
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Aman Gupta 961e4b26a7 llama-batch: add unit test (#25471)
* llama-batch: add unit test

* fix win32 builds

* add not implemented assertion in unused methods

* remove unreachable code
2026-07-10 11:04:31 +08:00

675 lines
23 KiB
C++

#include "testing.h"
#include "llama.h"
#include "../src/llama-batch.h"
#include "../src/llama-memory.h"
#include "../src/llama-vocab.h"
#include <cstdlib>
#include <initializer_list>
#include <map>
#include <string>
#include <utility>
#include <vector>
// mock memory that only provides per-sequence position ranges
struct mock_memory : public llama_memory_i {
std::map<llama_seq_id, std::pair<llama_pos, llama_pos>> ranges; // seq_id -> [pos_min, pos_max]
llama_memory_context_ptr init_batch(llama_batch_allocr &, uint32_t, bool) override { GGML_ASSERT(false && "not implemented"); }
llama_memory_context_ptr init_full() override { GGML_ASSERT(false && "not implemented"); }
llama_memory_context_ptr init_update(llama_context *, bool) override { GGML_ASSERT(false && "not implemented"); }
bool get_can_shift() const override { GGML_ASSERT(false && "not implemented"); }
void clear(bool) override { GGML_ASSERT(false && "not implemented"); }
bool seq_rm (llama_seq_id, llama_pos, llama_pos) override { GGML_ASSERT(false && "not implemented"); }
void seq_cp (llama_seq_id, llama_seq_id, llama_pos, llama_pos) override { GGML_ASSERT(false && "not implemented"); }
void seq_keep(llama_seq_id) override { GGML_ASSERT(false && "not implemented"); }
void seq_add (llama_seq_id, llama_pos, llama_pos, llama_pos) override { GGML_ASSERT(false && "not implemented"); }
void seq_div (llama_seq_id, llama_pos, llama_pos, int) override { GGML_ASSERT(false && "not implemented"); }
llama_pos seq_pos_min(llama_seq_id seq_id) const override {
auto it = ranges.find(seq_id);
return it == ranges.end() ? -1 : it->second.first;
}
llama_pos seq_pos_max(llama_seq_id seq_id) const override {
auto it = ranges.find(seq_id);
return it == ranges.end() ? -1 : it->second.second;
}
std::map<ggml_backend_buffer_type_t, size_t> memory_breakdown() const override { return {}; }
void state_write(llama_io_write_i &, llama_seq_id, llama_state_seq_flags) const override { GGML_ASSERT(false && "not implemented"); }
void state_read (llama_io_read_i &, llama_seq_id, llama_state_seq_flags) override { GGML_ASSERT(false && "not implemented"); }
};
// builds embedding batches - an empty llama_vocab rejects all token ids, so
// the tests use embeddings everywhere except the token validation tests
struct batch_builder {
uint32_t n_embd;
std::vector<float> embd;
std::vector<llama_pos> pos;
std::vector<int32_t> n_seq_id;
std::vector<int8_t> logits;
std::vector<std::vector<llama_seq_id>> seq;
std::vector<llama_seq_id *> seq_ptr;
batch_builder(uint32_t n_embd = 2) : n_embd(n_embd) {}
// embd values are 100*i + k so that ubatch contents can be traced back to batch indices
void add(llama_pos p, std::initializer_list<llama_seq_id> seq_ids, bool output) {
const int32_t i = (int32_t) seq.size();
for (uint32_t k = 0; k < n_embd; ++k) {
embd.push_back(100.0f*i + k);
}
pos.push_back(p);
n_seq_id.push_back((int32_t) seq_ids.size());
seq.emplace_back(seq_ids);
logits.push_back(output ? 1 : 0);
}
llama_batch make(bool with_pos = true, bool with_seq = true, bool with_logits = true) {
seq_ptr.clear();
for (auto & s : seq) {
seq_ptr.push_back(s.data());
}
seq_ptr.push_back(nullptr);
llama_batch res = {};
res.n_tokens = (int32_t) seq.size();
res.embd = embd.data();
res.pos = with_pos ? pos.data() : nullptr;
res.n_seq_id = with_seq ? n_seq_id.data() : nullptr;
res.seq_id = with_seq ? seq_ptr.data() : nullptr;
res.logits = with_logits ? logits.data() : nullptr;
return res;
}
};
static void test_init(testing & t) {
llama_vocab vocab;
t.test("rejects_n_seq_max_too_large", [&](testing & t) {
batch_builder bb;
bb.add(0, {0}, true);
llama_batch_allocr ba(1);
t.assert_true(!ba.init(bb.make(), vocab, nullptr, bb.n_embd, LLAMA_MAX_SEQ + 1, false));
});
t.test("rejects_invalid_token", [&](testing & t) {
llama_token tok = 0; // empty vocab -> every token id is out of range
llama_batch batch = llama_batch_get_one(&tok, 1);
llama_batch_allocr ba(1);
t.assert_true("token id >= n_tokens", !ba.init(batch, vocab, nullptr, 0, 1, false));
tok = -1;
t.assert_true("negative token id", !ba.init(batch, vocab, nullptr, 0, 1, false));
});
t.test("rejects_invalid_seq_id", [&](testing & t) {
llama_batch_allocr ba(1);
{
batch_builder bb;
bb.add(0, {4}, true);
t.assert_true("seq_id >= n_seq_max", !ba.init(bb.make(), vocab, nullptr, bb.n_embd, 4, false));
}
{
batch_builder bb;
bb.add(0, {-1}, true);
t.assert_true("negative seq_id", !ba.init(bb.make(), vocab, nullptr, bb.n_embd, 4, false));
}
});
t.test("autofill_defaults", [&](testing & t) {
batch_builder bb;
for (int i = 0; i < 4; ++i) {
bb.add(0, {0}, false);
}
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(false, false, false), vocab, nullptr, bb.n_embd, 4, false));
const llama_batch & batch = ba.get_batch();
t.assert_equal(4u, ba.get_n_tokens());
for (int i = 0; i < 4; ++i) {
t.assert_equal("pos defaults to 0..n-1", i, batch.pos[i]);
t.assert_equal("n_seq_id defaults to 1", 1, batch.n_seq_id[i]);
t.assert_equal("seq_id defaults to 0", 0, batch.seq_id[i][0]);
}
t.assert_equal("only the last token is an output", 1u, ba.get_n_outputs());
t.assert_equal(0, (int) batch.logits[0]);
t.assert_equal(1, (int) batch.logits[3]);
t.assert_equal(0, ba.seq_pos_min(0));
t.assert_equal(3, ba.seq_pos_max(0));
t.assert_equal(-1, ba.seq_pos_min(1));
});
t.test("output_all", [&](testing & t) {
batch_builder bb;
for (int i = 0; i < 4; ++i) {
bb.add(i, {0}, false);
}
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(true, true, false), vocab, nullptr, bb.n_embd, 4, true));
t.assert_equal(4u, ba.get_n_outputs());
});
t.test("explicit_logits", [&](testing & t) {
batch_builder bb;
bb.add(0, {0}, true);
bb.add(1, {0}, false);
bb.add(2, {0}, true);
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(), vocab, nullptr, bb.n_embd, 4, false));
t.assert_equal(2u, ba.get_n_outputs());
llama_ubatch ub = ba.split_simple(10);
t.assert_equal(3u, ub.n_tokens);
t.assert_equal(1, (int) ub.output[0]);
t.assert_equal(0, (int) ub.output[1]);
t.assert_equal(1, (int) ub.output[2]);
const auto & out_ids = ba.get_out_ids();
t.assert_equal((size_t) 2, out_ids.size());
t.assert_equal(0, out_ids[0]);
t.assert_equal(2, out_ids[1]);
});
t.test("pos_from_memory", [&](testing & t) {
mock_memory mem;
mem.ranges[0] = {0, 9};
batch_builder bb;
for (int i = 0; i < 3; ++i) {
bb.add(0, {0}, false);
}
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(false, true, false), vocab, &mem, bb.n_embd, 4, false));
t.assert_equal("pos continues after memory", 10, ba.seq_pos_min(0));
t.assert_equal(12, ba.seq_pos_max(0));
});
t.test("pos_continuity_with_memory", [&](testing & t) {
mock_memory mem;
mem.ranges[0] = {0, 9};
llama_batch_allocr ba(1);
{
batch_builder bb;
bb.add(10, {0}, false);
bb.add(11, {0}, true);
t.assert_true("pos_max + 1 is accepted", ba.init(bb.make(), vocab, &mem, bb.n_embd, 4, false));
}
{
batch_builder bb;
bb.add(11, {0}, false);
bb.add(12, {0}, true);
t.assert_true("gap after memory is rejected", !ba.init(bb.make(), vocab, &mem, bb.n_embd, 4, false));
}
{
batch_builder bb;
bb.add(9, {0}, false);
bb.add(10, {0}, true);
t.assert_true("overlap with memory is rejected", !ba.init(bb.make(), vocab, &mem, bb.n_embd, 4, false));
}
});
t.test("rejects_non_continuous_positions", [&](testing & t) {
batch_builder bb;
bb.add(0, {0}, false);
bb.add(1, {0}, false);
bb.add(3, {0}, true);
llama_batch_allocr ba(1);
t.assert_true(!ba.init(bb.make(), vocab, nullptr, bb.n_embd, 4, false));
});
t.test("rejects_decreasing_positions", [&](testing & t) {
batch_builder bb;
const llama_pos pos[7] = {4, 5, 0, 1, 6, 2, 3};
const llama_seq_id seq[7] = {0, 0, 1, 1, 0, 1, 0};
for (int i = 0; i < 7; ++i) {
bb.add(pos[i], {seq[i]}, false);
}
// seq 0 sees positions 4,5,6,3 in batch order -> the trailing 3 decreases
llama_batch_allocr ba(1);
t.assert_true(!ba.init(bb.make(true, true, false), vocab, nullptr, bb.n_embd, 4, false));
});
t.test("allows_equal_positions_in_seq", [&](testing & t) {
batch_builder bb;
bb.add(0, {0}, false);
bb.add(0, {0}, false);
bb.add(1, {0}, true);
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(true, true, false), vocab, nullptr, bb.n_embd, 4, false));
});
t.test("rejects_coupled_diverged_seqs", [&](testing & t) {
batch_builder bb;
bb.add(6, {0, 1}, true);
llama_batch_allocr ba(1);
mock_memory mem;
mem.ranges[0] = {0, 5};
mem.ranges[1] = {2, 5}; // same pos_max, different pos_min -> diverged
t.assert_true(!ba.init(bb.make(), vocab, &mem, bb.n_embd, 4, false));
mem.ranges[1] = {0, 5};
t.assert_true(ba.init(bb.make(), vocab, &mem, bb.n_embd, 4, false));
});
}
static void test_split(testing & t) {
llama_vocab vocab;
t.test("split_simple_chunks", [&](testing & t) {
batch_builder bb;
for (int i = 0; i < 5; ++i) {
bb.add(i, {0}, i == 4);
}
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(), vocab, nullptr, bb.n_embd, 4, false));
llama_ubatch ub = ba.split_simple(2);
t.assert_equal(2u, ub.n_tokens);
t.assert_true(!ub.equal_seqs());
t.assert_equal(1u, ub.n_seqs_unq);
t.assert_equal(0, ub.seq_id_unq[0]);
t.assert_equal(0, ub.seq_idx[0]);
for (int i = 0; i < 2; ++i) {
t.assert_equal(i, ub.pos[i]);
t.assert_equal(1, ub.n_seq_id[i]);
t.assert_equal(0, ub.seq_id[i][0]);
t.assert_equal(100.0f*i, ub.embd[i*bb.n_embd]);
t.assert_equal(100.0f*i + 1, ub.embd[i*bb.n_embd + 1]);
}
ub = ba.split_simple(2);
t.assert_equal(2u, ub.n_tokens);
t.assert_equal(2, ub.pos[0]);
t.assert_equal(3, ub.pos[1]);
ub = ba.split_simple(2);
t.assert_equal(1u, ub.n_tokens);
t.assert_equal(4, ub.pos[0]);
t.assert_equal(1, (int) ub.output[0]);
t.assert_equal(5u, ba.get_n_used());
ub = ba.split_simple(2);
t.assert_equal("batch is consumed", 0u, ub.n_tokens);
const auto & out_ids = ba.get_out_ids();
t.assert_equal((size_t) 1, out_ids.size());
t.assert_equal(4, out_ids[0]);
});
t.test("split_reset_allows_resplit", [&](testing & t) {
batch_builder bb;
for (int i = 0; i < 3; ++i) {
bb.add(i, {0}, i == 2);
}
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(), vocab, nullptr, bb.n_embd, 4, false));
while (ba.split_simple(1).n_tokens > 0) {
}
t.assert_equal(3u, ba.get_n_used());
ba.split_reset();
t.assert_equal(0u, ba.get_n_used());
llama_ubatch ub = ba.split_simple(10);
t.assert_equal(3u, ub.n_tokens);
});
t.test("split_equal_unequal_lengths", [&](testing & t) {
batch_builder bb;
for (int i = 0; i < 4; ++i) {
bb.add(i, {0}, i == 3);
}
for (int i = 0; i < 2; ++i) {
bb.add(i, {1}, i == 1);
}
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(), vocab, nullptr, bb.n_embd, 4, false));
llama_ubatch ub = ba.split_equal(8, false, 0);
t.assert_true(ub.equal_seqs());
t.assert_equal("both seqs advance by the shorter length", 4u, ub.n_tokens);
t.assert_equal(2u, ub.n_seq_tokens);
t.assert_equal(2u, ub.n_seqs);
t.assert_equal(2u, ub.n_seqs_unq);
// tokens are grouped per sequence set: [s0 s0 s1 s1]
t.assert_equal(0, ub.seq_id[0][0]);
t.assert_equal(0, ub.seq_id[1][0]);
t.assert_equal(1, ub.seq_id[2][0]);
t.assert_equal(1, ub.seq_id[3][0]);
t.assert_equal(0, ub.pos[0]);
t.assert_equal(1, ub.pos[1]);
t.assert_equal(0, ub.pos[2]);
t.assert_equal(1, ub.pos[3]);
ub = ba.split_equal(8, false, 0);
t.assert_equal("only seq 0 remains", 2u, ub.n_tokens);
t.assert_equal(1u, ub.n_seqs);
t.assert_equal(2, ub.pos[0]);
t.assert_equal(3, ub.pos[1]);
ub = ba.split_equal(8, false, 0);
t.assert_equal(0u, ub.n_tokens);
t.assert_equal(6u, ba.get_n_used());
});
t.test("split_equal_coupled", [&](testing & t) {
batch_builder bb;
bb.add(0, {0, 1}, false);
bb.add(1, {0, 1}, true);
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(), vocab, nullptr, bb.n_embd, 4, false));
llama_ubatch ub = ba.split_equal(4, true, 0);
t.assert_equal("sequential split rejects coupled seqs", 0u, ub.n_tokens);
ub = ba.split_equal(4, false, 0);
t.assert_equal(2u, ub.n_tokens);
t.assert_equal("one sequence set", 1u, ub.n_seqs);
t.assert_equal("two unique seq ids", 2u, ub.n_seqs_unq);
t.assert_equal(2, ub.n_seq_id[0]);
t.assert_equal(0, ub.seq_idx[0]);
t.assert_equal(1, ub.seq_idx[1]);
});
t.test("split_seq_per_sequence", [&](testing & t) {
batch_builder bb;
for (llama_seq_id s = 0; s < 3; ++s) {
bb.add(0, {s}, false);
bb.add(1, {s}, true);
}
llama_batch_allocr ba(1);
t.assert_true(ba.init(bb.make(), vocab, nullptr, bb.n_embd, 4, false));
for (llama_seq_id s = 0; s < 3; ++s) {
llama_ubatch ub = ba.split_seq(8);
t.assert_equal(2u, ub.n_tokens);
t.assert_equal(1u, ub.n_seqs);
t.assert_equal(s, ub.seq_id[0][0]);
t.assert_equal(s, ub.seq_id_unq[0]);
}
t.assert_equal(0u, ba.split_seq(8).n_tokens);
t.assert_equal(6u, ba.get_n_used());
});
t.test("ubatch_reserve", [&](testing & t) {
llama_batch_allocr ba(1);
llama_ubatch ub = ba.ubatch_reserve(3, 2);
t.assert_equal(6u, ub.n_tokens);
t.assert_equal(3u, ub.n_seq_tokens);
t.assert_equal(2u, ub.n_seqs);
t.assert_equal(2u, ub.n_seqs_unq);
t.assert_true(ub.equal_seqs());
t.assert_equal(0, ub.seq_id_unq[0]);
t.assert_equal(1, ub.seq_id_unq[1]);
t.assert_true(ub.token != nullptr);
t.assert_true(ub.embd == nullptr);
});
}
static void test_keep_tail(testing & t) {
llama_vocab vocab;
// batch with n_tokens[s] tokens for each seq s, output on the last token of each seq
auto make_batch = [](batch_builder & bb, std::initializer_list<int> n_tokens) {
llama_seq_id s = 0;
for (int n : n_tokens) {
for (int i = 0; i < n; ++i) {
bb.add(i, {s}, i == n - 1);
}
++s;
}
return bb.make();
};
t.test("noop_when_seqs_complete", [&](testing & t) {
batch_builder bb;
llama_batch_allocr ba(1);
t.assert_true(ba.init(make_batch(bb, {2, 2}), vocab, nullptr, bb.n_embd, 4, false));
llama_ubatch ub = ba.split_equal(4, false, 2);
t.assert_equal("both seqs fit whole", 4u, ub.n_tokens);
t.assert_equal(2u, ub.n_seqs);
t.assert_equal(2u, ub.n_seq_tokens);
t.assert_equal(0u, ba.split_equal(4, false, 2).n_tokens);
});
t.test("defers_seq_with_short_remainder", [&](testing & t) {
batch_builder bb;
llama_batch_allocr ba(1);
t.assert_true(ba.init(make_batch(bb, {2, 3}), vocab, nullptr, bb.n_embd, 4, false));
// expansion stops at 2 tokens per seq: seq 0 completes, seq 1 would be left
// with 1 < n_keep_tail remaining, so it is deferred entirely
llama_ubatch ub = ba.split_equal(4, true, 2);
t.assert_equal(2u, ub.n_tokens);
t.assert_equal(1u, ub.n_seqs);
t.assert_equal(0, ub.seq_id[0][0]);
t.assert_equal(2u, ba.get_n_used());
ub = ba.split_equal(4, true, 2);
t.assert_equal("deferred seq comes back whole", 3u, ub.n_tokens);
t.assert_equal(1u, ub.n_seqs);
t.assert_equal(1, ub.seq_id[0][0]);
for (int i = 0; i < 3; ++i) {
t.assert_equal(i, ub.pos[i]);
}
t.assert_equal(5u, ba.get_n_used());
t.assert_equal(0u, ba.split_equal(4, true, 2).n_tokens);
});
t.test("completes_first_seq_when_all_violate", [&](testing & t) {
batch_builder bb;
llama_batch_allocr ba(1);
t.assert_true(ba.init(make_batch(bb, {3, 3}), vocab, nullptr, bb.n_embd, 4, false));
// expansion stops at 2 tokens per seq, leaving both with 1 < n_keep_tail remaining;
// seq 0 still fits in n_ubatch, so it is extended to completion and emitted alone
llama_ubatch ub = ba.split_equal(4, false, 2);
t.assert_equal(3u, ub.n_tokens);
t.assert_equal(1u, ub.n_seqs);
t.assert_equal(3u, ub.n_seq_tokens);
t.assert_equal(0, ub.seq_id[0][0]);
for (int i = 0; i < 3; ++i) {
t.assert_equal(i, ub.pos[i]);
}
t.assert_equal(3u, ba.get_n_used());
ub = ba.split_equal(4, false, 2);
t.assert_equal(3u, ub.n_tokens);
t.assert_equal(1, ub.seq_id[0][0]);
t.assert_equal(6u, ba.get_n_used());
});
t.test("truncates_to_preserve_tail", [&](testing & t) {
batch_builder bb;
llama_batch_allocr ba(1);
t.assert_true(ba.init(make_batch(bb, {5}), vocab, nullptr, bb.n_embd, 4, false));
// 4 tokens would leave a remainder of 1, and the seq does not fit in n_ubatch,
// so the ubatch is truncated until n_keep_tail tokens remain
llama_ubatch ub = ba.split_equal(4, false, 2);
t.assert_equal(3u, ub.n_tokens);
t.assert_equal(1u, ub.n_seqs);
t.assert_equal(2, ub.pos[2]);
t.assert_equal(3u, ba.get_n_used());
ub = ba.split_equal(4, false, 2);
t.assert_equal("trailing tokens stay in one ubatch", 2u, ub.n_tokens);
t.assert_equal(3, ub.pos[0]);
t.assert_equal(4, ub.pos[1]);
t.assert_equal(1, (int) ub.output[1]);
t.assert_equal(5u, ba.get_n_used());
});
t.test("keeps_full_ubatch_with_sufficient_remainder", [&](testing & t) {
batch_builder bb;
llama_batch_allocr ba(1);
t.assert_true(ba.init(make_batch(bb, {6}), vocab, nullptr, bb.n_embd, 4, false));
llama_ubatch ub = ba.split_equal(4, false, 2);
t.assert_equal("remainder >= n_keep_tail, no truncation", 4u, ub.n_tokens);
ub = ba.split_equal(4, false, 2);
t.assert_equal(2u, ub.n_tokens);
t.assert_equal(4, ub.pos[0]);
t.assert_equal(5, ub.pos[1]);
t.assert_equal(6u, ba.get_n_used());
});
t.test("multi_seq_prefix_kept", [&](testing & t) {
batch_builder bb;
llama_batch_allocr ba(1);
t.assert_true(ba.init(make_batch(bb, {3, 4}), vocab, nullptr, bb.n_embd, 6, false));
// expansion stops at 3 tokens per seq: seq 0 completes, seq 1 has 1 < n_keep_tail
// remaining and is deferred even though its tokens were already gathered
llama_ubatch ub = ba.split_equal(6, true, 2);
t.assert_equal(3u, ub.n_tokens);
t.assert_equal(1u, ub.n_seqs);
t.assert_equal(0, ub.seq_id[0][0]);
t.assert_equal(3u, ba.get_n_used());
ub = ba.split_equal(6, true, 2);
t.assert_equal(4u, ub.n_tokens);
t.assert_equal(1, ub.seq_id[0][0]);
t.assert_equal(7u, ba.get_n_used());
});
}
static void test_mrope(testing & t) {
llama_vocab vocab;
t.test("pos_layout_and_split", [&](testing & t) {
const uint32_t n_pos = 4;
const uint32_t n_embd = 2;
batch_builder bb(n_embd);
bb.add(10, {0}, false);
bb.add(11, {0}, true);
// M-RoPE positions for embeddings are laid out [n_pos][n_tokens]
std::vector<llama_pos> pos = {
10, 11, // temporal
5, 6, // y
7, 8, // x
0, 0,
};
llama_batch batch = bb.make(false, true, true);
batch.pos = pos.data();
llama_batch_allocr ba(n_pos);
t.assert_true(ba.init(batch, vocab, nullptr, n_embd, 4, false));
llama_ubatch ub = ba.split_simple(2);
t.assert_equal(2u, ub.n_tokens);
t.assert_equal(n_pos, ub.n_pos);
t.assert_true(ub.is_pos_2d());
const llama_pos expected[8] = {10, 11, 5, 6, 7, 8, 0, 0};
for (int i = 0; i < 8; ++i) {
t.assert_equal(expected[i], ub.pos[i]);
}
});
t.test("pos_jump_allowed", [&](testing & t) {
const uint32_t n_pos = 4;
const uint32_t n_embd = 2;
mock_memory mem;
mem.ranges[0] = {0, 9};
llama_batch_allocr ba(n_pos);
auto try_pos = [&](llama_pos p0) {
batch_builder bb(n_embd);
bb.add(p0, {0}, true);
std::vector<llama_pos> pos = {p0, 1, 1, 0};
llama_batch batch = bb.make(false, true, true);
batch.pos = pos.data();
return ba.init(batch, vocab, &mem, n_embd, 4, false);
};
t.assert_true("gap after memory is allowed", try_pos(15));
t.assert_true("overlap is allowed for embd", try_pos(9));
t.assert_true("pos behind memory is rejected", !try_pos(8));
});
}
int main(int argc, char ** argv) {
testing t;
const char * verbose = getenv("LLAMA_TEST_VERBOSE");
if (verbose) {
t.verbose = std::string(verbose) == "1";
}
if (!t.verbose) {
llama_log_set([](ggml_log_level, const char *, void *) {}, nullptr);
}
if (argc > 1) {
t.set_filter(argv[1]);
}
t.test("init", test_init);
t.test("split", test_split);
t.test("keep_tail", test_keep_tail);
t.test("mrope", test_mrope);
return t.summary();
}