Let $\gamma: [a,b]\to\mathbb{R}^d$ be a smooth (i.e. $\gamma\in C^\infty (\mathbb{R}))$ and regular ($\gamma^\prime(t)\neq \vec 0$) curve with arc-length defined by $$\gamma(t)=(\gamma_1(t),\dots,\gamma_d(t)).$$

Assume that $\gamma_j(t),\gamma_j^\prime(t)\neq 0$ for $1\le j\le d$. 

Define a partition $P=\{x_0,x_1,\dots,x_n\}$ on $[a,b]$ by:
$$
x_m=\begin{cases}
a & m=0\\
b & m=n \\
\max_{t\in[x_{m-1},b]} \{\forall t\in [a,x_{m-1}] \forall1\le j\le d-1,\gamma_j(t)\neq\gamma_j(s)\}& \text{otherwise}
\end{cases}.
$$
Roughly speaking, this partition divides $\gamma(t)$ to injective graphs in respect to last coordinate. 

My question is "how large can P be?". To put it in other words, Can we find a curve $\gamma$ with $|P| = \aleph_0$? ${\mathfrak c}$? (where $|P|$ denotes cardinality of the set).